Vehicle interactive electronic wireless air pressure system&#39;s information: &#34;VIEW A PSI&#34;

ABSTRACT

A vehicle tire communication and information system for viewing air psi and other characteristics that affects psi in a tire includes un-obstructive sensors embedded in a silicon substrate and etched in a re-enforced micro-fibered material to enable excellent detection platform, sensitivity, and selectivity within the detection environment. The embedded sensors facilitate detection and communication efficiency and transforms electrical energy into acoustic energy indicative of data transmission to a wireless electronic control module, allowing a nitride membrane to march the acoustic impedance of the air inside the tire to enable pressure waves indicative of the tire pressure.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to Interactive television with embedded camera for enabling security vigilant monitoring and networking, and more specifically, to distributing detected information within a network through a control server.

2. Related Art

The innovation of the information age has revealed new and exciting opportunities for interactive high definition television capabilities. Personal televisions have been deployed in a variety of arenas to gain image clarity and efficiencies, reduce cost, and increase productivity. Miniaturization and portability have made personal televisions more accessible and a more valued tool in many business environments. Personal televisions have also become a very useful tool in non-business environments, including educational institutions and homes.

Home television network in connection with a computer means are gaining increased popularity. Within a home, multiple personal televisions can be connected together in the home and/or

for office computer to permit a home occupant to share security data and other data without having to manually carry a camera from one room to another. The television network in connection with a computer means also permits the home occupant to receive detected data, share printers, fax machines, and other devices or reach other distant destination. Internet access facilities can also be provided to permit access to external networks and services. Thus, a home occupant can operate an interactive high definition television through his cell phone in communication with a control server to gain instant access to information source from anywhere in the world.

Despite the increasing presence of home television network in connection with a computer means, several significant problems must be overcome. For example, installing a home network can be time extensive and expensive to deploy. Additionally, there is no easy method to integrate home television network in connection with a computer means with other residential, commercial/industrial devices, destination, such as televisions, stereos, DVD distributors, and other home electronics. Being able to efficiently distribute digital audio/video (AV) data among personal televisions and other AV devices, destination such as, televisions, DVD distributors, PVRs, etc. is complicated by differing and evolving detection and communications standards and/or formats.

Another significant challenge is being able to effectively control the networked residential, commercial/industrial devices, destination. Although a remote control unit can be trained to send signals to components of an entertainment center such as, a television, stereo, and VCR, there is no known central device that can communicate and control multiple personal televisions and other analog and/or digital devices, destination at a offices and residence or office environment.

Although the combination of improved interactive high definition television capabilities and global access to detection information has resulted in significant advancements in the information processing age, there exists a need for a simple, inexpensive, yet versatile system that can integrate the functions of interactive high definition television into multiple security and detection device for residential, commercial/industrial/office and connected to a residential, commercial/industrial/office network and access-able from any remote location to enable home protection from physical theft, un-authorized entry, burglary, etc.

SUMMARY OF THE INVENTION

The present invention provides a method, system and programmed interactive high definition television product for security monitoring and for managing a plurality of devices, destination and/or applications within an environment, such as a home, business, school, etc, as well as its surrounding areas. A control server comprises one or more servers or processing systems, and enables centralized command and control of the devices, destination and/or applications.

In one embodiments of the present invention, the devices, destination means and/or applications include entertainment and communication equipment such as, television, telephone, intercoms, etc. The present invention further includes entertainment systems such as, televisions, CD/DVD distributors, computer applications, stereos, etc. The devices and entertainment system are coupled to a monitoring system such as, computers, security cameras, and baby monitor with/without cameras, etc. to enable a security system. The security systems further include devices such as, body heat sensors, fire alarms, burglary alarm, glass alarm, sprinkler systems, door lock or window sensors, and personal computer such as, servers, desktops, notebooks, notepads, personal digital assistants, or the like.

In other embodiments of the present invention, the control server distributes information including video, audio, voice, text, graphics, control messages, detection data etc. to coded addresses and/or other applications. The control server supports video/audio serving, telephony, messaging, file sharing, internetworking, and/or security monitoring.

Yet in other embodiments of the present invention, a detection platform that is small in physical size, has access to power lines for continuous and uninterrupted electrical power, and is physically located within the body of a television to facilitate transmission and reception of wireless signals is suitable for housing or hosting the interactive hardware comprising the control server. In an instant embodiment, a smoke detector serves as a detection platform for the control server. The smoke detector's ceiling-wall mounted base and direct connection to a home or office's existing voltage AC power line provides an ideal platform for the control server and enables information to be transported throughout the controlled environment either through a wireless connection or through the power line. The control server can be housed within a wired/wireless access point, which provides the control server with “always-on” and wired/wireless connectivity.

Still in other embodiments of the present invention, a wireless controller such as a digital personal assistant, cell phone, wireless notepad, etc. enable a home occupant to interact with the control server. Such interaction includes altering the configuration and performance of the other devices, destination and/or applications. Accordingly, the wireless controller provides remote access to other devices, destination and/or applications, and enables the home occupant to control other functions and/or operations from any location within the environment. In one embodiment, the control server is located within the wireless controller. In another embodiment, the control server is located at a centralized location that is distinct from the wireless controller.

In other embodiments of the present invention, the wireless controllers are equipped with location-awareness and/or home occupant-awareness functionality. As such, the control server in communication with a television has the ability to track and/or monitor the position of the wireless controllers and enable personalized configurations and data transmission based on the home occupant identity.

In yet another embodiment, one or more control microprocessor 105 for enabling communication can be established, either automatically by the control server and the home occupant, to control the operations, detections, and/or functions of the interactive high definition television system components. A control microprocessor 105 s includes a set of commands that, when executed, enables the control server to manage multiple operations and/or functions of one or more of the television system and other components. The control microprocessor 105 s can be associated with a control microprocessor 105 s detection data for future recall and execution. The control microprocessors 105 are stored at the control server. In an embodiment, the wireless controller is programmable to issue a generic control request to the control server to thereby execute the sequence of commands from the control microprocessor 105.

BRIEF DESCRIPTION OF THE DRAWINGS/FIGURES

The accompanying drawings, which are incorporated herein and form part of the specification, illustrate the present invention and, together with the description, further serve to explain the principles of the invention and to enable a person skilled in the pertinent art to make and use the invention. In the drawings, like reference numbers indicate identical or functionally similar elements. Additionally, the leftmost digit(s) of a reference number identifies the drawing in which the reference number first appears.

FIG. 1 illustrates a control system according to an embodiment of the present invention.

FIG. 2 illustrates a control server with archival and/or retrieval components according to an embodiment of the present invention.

FIG. 3 illustrates a control server according to an embodiment of the present invention.

FIG. 4A illustrates a positioning mechanism for a control system according to an embodiment of the present invention.

FIG. 4B illustrates a positioning mechanism for a control system according to another embodiment of the present invention

FIG. 5 illustrates a flow diagram for tracking and/or monitoring system components according to an embodiment of the present invention.

FIG. 6 illustrates a flow diagram for commanding and/or controlling system components in response to home occupant location according to an embodiment of the present invention.

FIG. 7 illustrates home occupant interface for presenting control options according to an embodiment of the present invention.

FIG. 8 is an example computer system useful for implementing the present invention.

FIG. 9 illustrates a flow diagram for defining control microprocessor 105 s to watch a movie recording according to an embodiment of the present invention.

FIG. 10 illustrates a flow diagram for activating the control microprocessor 105 s of FIG. 9 according to an embodiment of the present invention.

FIG. 11 illustrates a control system according to another embodiment of the present invention.

FIG. 12 illustrates a control system according to another embodiment of the present invention.

FIG. 13 illustrates a control system according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is directed towards the centralized high definition interactive definition television having camera to enable security and monitoring command and control of a plurality of devices, destination and/or applications within a controlled environment, such as a home, business, school, etc. Therefore in many embodiments of the present invention, the controlled environment is a residential, commercial/industrial/industrial environment. The residential, commercial/industrial environment pertains to the confines of a home, industries, companies, apartment, mobile home, houseboat, or other types of offices and residences. However in embodiments, the residential, commercial/industrial environment includes the surrounding area of the offices and residence, as well as any shelters, constructs, improvements, or the like, within a designated perimeter.

In other embodiments, the present invention is implemented in non-residential, commercial/industrial/industrial environments. A non-residential, commercial/industrial environment includes, but is not limited to, an office complex, suite of small offices, production studio, warehouse, entertainment arena, health care facility, hotel, vacation resort, aircraft, ship, automobile, or the like. In embodiments, the controlled environment for the non-residential, commercial/industrial embodiments includes not only the actual confines of the aforementioned structures but also other surroundings within a designated perimeter.

Within the controlled environment of the present invention, one or more controlled servers, or the like, provide a centralized command and control of the server for distributing information, including video, audio, voice, text, graphics, control messages, etc. to the other devices, destination and/or applications. The devices, destination means and/or applications include entertainment and communication equipment such as, telephones, intercoms, etc. in communication with the entertainment systems such as, televisions, CD/DVD distributors, computer applications, stereos, etc. to enable security monitoring. The monitoring system further include security cameras, baby monitor with/without cameras and the like coupled to the safety/security systems such as, body heat sensors, fire alarms, burglary alarm, glass alarm, sprinkler systems, door lock or window sensors, personal televisions, desktops, notebooks, notepads, personal digital assistants, or the like.

In an embodiment, a wireless device such as a digital personal assistant, cell phone, wireless control module, wireless notepad, etc. enables a home occupant to interact with the centralized command and control server. Such interaction includes checking and altering the configuration and performance of the other devices, destination and/or applications within the controlled environment. Accordingly, the wireless device provides remote access to other devices, destination and/or applications, and enables the home occupant to control other functions and/or operations from any location within the controlled environment.

For example, a home occupant can operate the wireless device to receive a recorded or live video about detection in his home from any location within the controlled environment. The video can be presented on a display coupled to the wireless device or a monitor within the area that the home occupant is presently located. Accordingly, the home occupant would be able to watch a television program while lounging and enabling security monitoring. Additionally, the home occupant would be able to view detection video from a baby monitor with/without camera or a security camera on the wireless display device or another display, such as a wireless notepad, cell phone screen, desktop computer, television screen, etc.

In embodiments, a home occupant is able to view or listen to media and detected data being presented on other televisions, personal televisions, and/or audio systems. As such, current home occupant can monitor their home through television programs via web sites, and/or audio/video recordings that could be viewed by other children in other rooms. The present invention includes protocols that enable the current home occupant to block access to objectionable content for detection.

In other embodiments, a home occupant is able to access the centralized control server command and enable control through an external interface, such as the Internet. A home occupant is able to gain access to devices, destination and/or applications that are located within the controlled environment while the home occupant is at work or away from home. Therefore, the present invention permits a home occupant to log into the controlled environment and download or store data, receive feeds from the high definition interactive television serving as surveillance equipment, and open or secure locks on entry ways, or the like.

The present invention is implemented in residential, commercial/industrial and/or non-residential, commercial/industrial controlled environments. By way of example, the following embodiments are described with reference to a residential, commercial/industrial environment. However, it should be understood that the following embodiments could be modified to include non-residential, commercial/industrial, industrial environments as well.

Referring to FIG. 1 is an illustration of a server network control system 10 according to an embodiment of the present invention. The present invention contemplates analog and digital environments. System 10 is an innovative, inexpensive, and versatile residential, commercial/industrial network. As shown, system 10 includes a communications network 80 and/or Internet that interconnects a plurality of detection and optical components to enable the network. The system components include a telephone means 12, a positioning unit 120, a computer 16, a camera 18, a control module 20, a television 22, a control server 24, a monitor 28, a voice auditory/audio means 118, and residential and commercial/industrial application software 26. Other devices, destination and/or applications can also be included as a system component.

Functionally, the components of the interactive detector 122 may be broadly grouped as being either digital signal components or optical isolating component for detection. These components could be embedded in computers 106 and computer peripheral components and RF modulating audio and/or video signal components forming the interactive detector 122. Generally, the media and detected data components of the interactive detector 122 include the computer components of the interactive detector 122 for enabling communication in serial digital signal format. The media and detected data components of the interactive detector 122 include either analog or digital signal outputs. All of the components of the interactive detector 122 enable signals to be transmitted together with the received broadcasting signals indicative of collectively enabling transmission through the network in a shared mode, such as is seen in one of three networks allocated frequency bands.

The frequency band includes a 5.0 to 42.0 MHz band dedicated to the Data Over Cable Service Interface Specification (DOCSIS) for upstream digital signal communications between a home occupants personal television 22, computer 16 (PC) and the cable service provider's server, enabling the CATV broadcast band ranging from 55.24 MHz (CATV channel 2) to 997.25 MHz (CATV channel 158). In the present network for the invention, a portion of each broadcast signal spectrum both CATV and UHF broadcast television are reserved for internal network use as modulation frequencies for the media and detected data signals, which are transmitted through the network. The media and detected data signals include both audio and video content as may be available from the network connection components forming the interactive detector 122. At 150 square feet at least detection from at least an interactive detector 122 is positioned within an environment, a signal distribution length is received from at least 15 dB 600 MHz attenuated substantially to 0 dB. The active gain shaping counteracts the high frequency attenuation and provides a usable signal-to-noise ratio signal up to CATV channel 85 at approximately 600 MHz, which is beyond the network reserved RF spectrum. The RF amplifier 124 is connected to the CATV for empowering communication signals and has substantially flat gain from 50 MHz to 1000 MHz and 75 ohm characteristic input/output impedance. The impedance matches the characteristic impedance of the broadcast signal coaxial line 1 and the network's signal conductors 30-33 as seen in FIG. 1.

The amplified broadcast signals are presented on line 2 to known type slope equalization circuitry 55 assigned specifically to communicate with home occupants and security agencies. As the signal frequency increases the output loading is reduced and the shunt inductor reactance increases with frequency, thereby substantially reducing the attenuation of the higher signal frequencies. The gain shaped and notch filtered broadcast signals are presented at the output of the slope equalization circuitry on lines 3. The signals on lines 4,5 are presented through high pass frequency filters 67, 68 to network terminals 30, 31 where they are distributed by conductors 24, 25 to the components of the interactive detector 122 in locations 39, 40 as seen in FIG. 1. The high pass filters provide low impedance coupling of the broadcast signals to the network terminals while also blocking the low frequency signals that are simultaneously coupled to the terminals 30, 31 through low pass filters 69, 70 from the low frequency bus 71.

Conversely, low pass frequency filters 69, 70, having a nominal −3 dB frequency filter with a frequency range of 4.5 MHz, blocks the conditioned broadcast signals from the BALUM 80 from being coupled onto the low frequency bus 71. The low frequency bus 71 carries the low frequency detection data and information band signals and enables the command and control band signals which are coupled between each of the network terminals through low pass filters, such as the filters 69, 70 associated with the network terminals 30, 31. The BALUM 29 couples the high frequency signals through high pass frequency filters 72, 73, which are substantially similar to the high pass filters 67, 68 for the network terminals 26, 27 as shown in FIG. 1. Similarly, low pass frequency filters 74, 75, which are substantially similar to low pass filters 69, 70, block the high frequency broadcast signals from passing through to the low frequency bus 71 when detection is enabled.

In an embodiment, control server 24 is configured to support various operating systems or interchangeable operating system. Control server 24 is operable to query, receive, and/or write to various archival and/or retrieval components. The archival and/or retrieval components can be internal and/or external to control server 24, which is configured to receive compressed streams, filter the streams for metadata such as, date, time, source, etc., and store the streams and metadata for future retrieval. FIG. 2 shows control server 24 connected to various archival and/or retrieval (A/R) components according to an embodiment of the present invention. The A/R components include a media and detected data archive 04, a secondary control server 23, a DSS box having human body heat sensor 206, a cable box 17, a media and detected data recognizer 06, and a media and detected data analyzer 08, and other detection devices. The aforementioned archival and/or retrieval components are not intended to be an exhaustive listing. Other archival and/or retrieval components can be implemented and are deemed to be within the scope of the present invention.

The archival and/or retrieval components can be centrally located in the homes/offices, widely distributed throughout the home/offices and residence, or accessible from an external source such as, a web server device having communicating means over the global Internet via a network connection 90. Network connection 90 include a wired and/or wireless LAN or wide area network (WAN), such as an organization's intranet, a local internet, the global-based Internet including the World Wide Web “WWW,” an extranet, a virtual private network, licensed wireless telecommunications spectrum for digital cable and cell including CDMA, TDMA, GSM, EDGE, GPRS, CDMA2000, WCDMA FDD and/or TDD or TD-SCDMA technologies, or the like. Network connection 90 includes wired, wireless, or both transmission media, and detecting data means includes satellite, terrestrial such as fiber optic, copper, UTP, STP, coaxial, hybrid fiber-coaxial “HFC”, or the like, radio, free-space optics, microwave, and/or any other form or method of transmission.

Media and detected data archive 04 provides one or more storage mediums for various data including video and audio, and metadata. In this embodiments, media and detected data archive 04 includes a removable storage unit such as a zip disk, floppy disk, CD-ROM, etc. To support larger volumes of detection content, one or more integrated databases or a data warehouse system is used to store the content and support the control server 24. In the embodiments, media and detected data archive 04 includes a relational or object oriented “OO”/component based database management system, or the like, that controls the analyzer, storing, retrieving, and updating of relevant data and metadata in the database records. The database management system also controls data integration, enforces integrity rules and constraints including detection data integrity and detection data referential integrity, and enforces security constraints.

Still in this embodiments, media and detected data archive 04 is a scalable system that stores data on multiple disk arrays. Detection and communication data warehousing can be implemented with at least the SQL Server 2000 application, which is available from Microsoft Corporation, the Oracle 9i.™. Database system is available from Oracle Corporation “Redwood City, Calif.” or the like. Yet in this embodiments, media and detected data archive 04 supports Open Database Connectivity “ODBC” and/or Java Database Connectivity “JDBC” protocols. The media and detected data archive 04 further include and index file database system and/or a planner file database system.

Secondary control server 23 receives audio and/or video signals from television and/or interactive security detectors. Secondary control server 23 is one or more individual radio and/or television tuners and programmer. In addition to receiving interactive broadcast detection signals, control server 24 is also configurable to support recording capabilities. Detection communications are broadcast and/or recorded to media and detected data archive 04. The control server 24 includes one or more record/playback applications or devices such as media and detected data analyzer 08 and media and detected data recognizer 06. Media and detected data analyzer 08 can be a VCR distributor, DVD distributor, PVR, video server, virtual recorder, audio server, stereo, CD distributor, record distributor, audio tape or cassette distributor, digital audio tape recorder, and/or any other device or application that stores, records, generates, or plays back via magnetic, optical, electronic, or any other storage media. Media and detected data recognizer 06 records and plays back media and detected data and/or multimedia and detected data similar to media and detected data analyzer 08 functions. However, media and detected data recognizer 06 is capable of loading multiple recordings such as CD, DVD, etc. to be played without having to be reloaded.

Control server 24 provides centralized command and control of various functions within a controlled environment, such as system 10. The functions that are managed by control server 24 include video serving, audio serving, telephony, messaging, file sharing, Internet access, and security. According to other embodiments of the present invention, a home occupant operates control module 20 to establish or re-configure these functions and/or receive media and detected data from control server 24 or other system components, either directly from the system components or indirectly from the system components via control server 24.

FIG. 3 illustrates an embodiment of control server 24. Control server 24 includes wired/wireless communication links to various controller modules for security programming, monitoring, and for various system functions. Moreover, control server 24 includes application software to enable a video controller 106, an audio controller 108, a telephony controller 110, and a messaging controller 112, a file sharing controller 114, an external network interface controller 312, and a security controller 116. The controller modules are enabled to exchange signals with other system components via communications network. The controller modules are also enabled to exchange communications with other A/R components. As described with reference to FIG. 2, the A/R components include media and detected data archive 04, secondary control server 23, DSS box 15, cable box 17, media and detected data recognizer 06, media and detected data analyzer 08, and/or the like.

Control server 24 manages the distribution of information among the other system components. As described in greater detail below, control server 24 interacts with the other components to directly or indirectly distribute data including audio and/or video, voice, and/or control messages over communications network 80 and/or Internet. In an embodiment, control server 24 commands and controls the operation and/or functions of one or more of the other system components.

Telephone means 12 is one or more wired and/or wireless telecommunication devices

communication route and destination means. Telephone means 12 exchanges telecommunications signals over conventional residential, commercial/industrial telephone paths and communications network 80 and/or Internet. In an embodiment, telephone means 12 implements a voice over Internet Protocol (VoIP) to exchange voice communications over a television network wired/wirelessly or in connection with a computer means such as the global Internet, and makes the voice signals available to communications network 80 and/or Internet. In an embodiment, telephone means 12 includes facsimile functions.

Positioning unit 120 includes interactive detector 122 as described in U.S. Pat. No. 6,762,686 and designates spatial locations within the offices and residence that serves as the hosting environment for system 10. Positioning unit 120 is coupled to the other system components such as the control server 24 via a wired and/or wireless interface. Positioning unit 120 is operable to designate by coded means, a floor or room assignment within the offices and residence. Positioning unit 120 is also operable to designate a specific location within a floor or room. Moreover, positioning unit 120 can be situated inside/outside of the offices and residence to thereby, designate external areas of protection for the offices and residence. In an embodiment, positioning unit 120 is coupled to another system component. In another embodiment, multiple positioning units 120 are distributed throughout the offices and residence. For example, the positioning units 120 can be located within, or mounted to, a wall, door, ceiling, floor, or the like.

Computer 16 includes a wired and/or wireless personal television, personal digital assistant (PDA), enhanced telephone, personal television, or other data processing device linked to communications network 80 and/or Internet. As a personal interactive high definition television, computer 16 can be a desktop, cell phone, notebook, notepad, or the like. A display is coupled to computer 16 to provide a text or graphical home occupant's interface (GUI) and enable a home occupant to interactively communicate with control server 24. Input devices enable data destination for computer 16 and include a keyboard, cell phone, mouse, verbal command interface, mouse wheel, joystick, rudder pedals, touch screen, microphone, joystick, stylus, light pen, or any other type of peripheral unit.

Camera 18 is one or more video cameras, camcorders, or the like. The present invention contemplates both wired and wireless devices for allowing detection and enabling signal destination. Camera 18 can be a part of home security or monitoring system, such as a television screen, a computer screen, a baby monitor with/without camera, etc. In an embodiment, camera 18 is wired/wirelessly connected to a position unit 14, and includes a control unit that enables remote control of various camera functions, such as pan, tilt, zoom, focus, iris control, etc.

Control module 20 is a wired and/or wireless data processing device that enables a home occupant to interact with the detection system and send control messages to control server 24 and the other system components. Control module 20 can be a wireless or non-wireless version of the devices destination means listed as computer 16. For example, computer 16 can be cell phone, personal notebook or notepad computer, PDA, enhanced telephone, or other device linked to communications network 80 and/or Internet and including a display with the ability to interact with the other system components. Hence, control module 20 enables a home occupant to remotely control the operations of the various components of system 10. In an embodiment the display for control module 20 is capable of receiving video, text, and/or audio from the other system components. In an embodiment, control module 20 includes a flash ROM that enables wireless downloads and/or uploads.

Television 22 is a conventional television having embedded cameras with all features focused for enabling interactive detection. In an embodiment, television 22 is enhanced to support interactive and/or personal services. Personal services include monitoring, virtual recording, programming, pausing/rewinding live broadcasts, or the like. For example, television 22 can be a personal television with interactive means enhanced to support online communication and other radio frequencies transmission through web TV Networks. The television 22 includes means for enabling communication through cable and/or satellite receptions and in connection to a device having at least a PVR, VCR, or DVD distributor/recorder.

Monitor 28 is a wired or wireless display that supports closed-circuit viewing. In an embodiment, monitor 28 is a flat LCD positioned on a wall or standing on a desk, table, or counter top, etc. In an embodiment, monitor 28 receives a streaming screen saver that displays static or dynamic images of a photograph, portrait, etc. when monitor 28 is functioning in an inactive state. In another embodiment of the present invention, monitor 28 receives feeds from a television, stereo, or security/monitoring system such as a baby monitor with/without camera.

A voice auditory/audio means 118 is a wired or wireless audio system, such as a cell phone, stereo, audio vice server, CD/record/cassette distributor, MP3 distributor, etc. A voice auditory/audio means 118 can be a microphone as part of a security/monitoring system, such as interactive alarms “U.S. Pat. No. 6,762,686” a baby monitor with/without camera. In an embodiment, a voice auditory/audio means 118 includes one or more speakers with like audio outputs located throughout the offices and residence. In another embodiment, a voice auditory/audio means 118 is an intercom system, public/office announcement system, door answering service, or the like.

Communications network 80 and/or Internet provide a transmission medium for communicating among the system components. In embodiments, control server 24 polices all traffic among the other system components. As such, the exchange of information among the system components is routed or otherwise controlled via control server 24. In another embodiment, communications network 80 and/or Internet supports peer-to-peer communications. As such, the system components exchange audio, video, other data, and/or control messages directly with each other and without being centrally managed by security control server 24. Therefore, the present invention can be implemented without control server 24. In such one aspect of de-centralized embodiments, the control and management functions for the communications network 80 and/or Internet are distributed and shared by multiple system components so that the system components can communicate with each other over a wired and/or wireless medium without a central control server 24.

Communications network 80 and/or Internet are a wired and/or wireless local area network (LAN). Thus, communications network 80 and/or Internet includes wired, wireless, or both transmission media for detected data, including satellite, terrestrial such as fiber optic, copper, UTP, STP, coaxial, hybrid fiber coaxial (HFC), or the like, radio, microwave, free-space optics, and/or any other form of method of transmission not mention at this time.

In an embodiment using a wired transmission medium, communications network 80 and/or Internet are Ethernet LAN capable of supporting one hundred Mbps to one Gbps. Still in an embodiment, a CAT-5 cable, or the like, is coupled to control server 24 and is distributed to a location within each room. Yet, in an embodiment, the cable is distributed to each system component, such as television 22, monitor 28, etc. The system component includes an audio/video (AV) connector that is responsive to receive the cable.

In an embodiment using a wireless transmission medium, communications network 80 and/or Internet supports the IEEE standard 49.11(a), which specifies a wireless Ethernet protocol for large-sized video. Using this protocol, communications network 80 and/or Internet can handle up to fifty-four Mbps with an effective range of ninety feet. In another wireless embodiment, communications network 80 and/or Internet supports the IEEE standard 49.11(b), which specifies a wireless Ethernet protocol for small-size video. With this wireless protocol, communications network 80 and/or Internet are effective for ranges approximating 150-300 feet, and capable of supporting nominal bandwidth of 11 Mbps, with 4-5 Mbps effective bandwidth.

In an embodiment, communications network 80 and/or Internet include a telephone line and/or power line. In an embodiment, communications network 80 and/or Internet enables conventional electrical outlets and wiring to interconnect the system components and enable them to communicate with each other. In an embodiment, communications network 80 and/or Internet include communications technologies made available from the Home Phone and cable Networking Alliance or the like. Home technologies enable the operation of telephone services and home networking, including, but not limited to, video conferencing, video security, VoIP telephony, digital video networking, Internet sharing, and multi-home occupant gaming.

Communications network 80 and/or Internet include a central control server 24 to enable the system components to communicate with each other. In embodiments of the present invention, a detection platform that is small in physical size, has access to power lines for continuous and uninterrupted electrical power is physically located within the system to facilitate transmission and reception of wireless signals suitable for providing housing, hosting, or the like and for enabling detection through central control server 24 as shown on. FIG. 11. The figure illustrates an embodiment of server network control system 10 that includes a wireless network access point 1180 as a detection platform for home occupants and in communication with control server 24. Detection and communication wireless access point 180 provides control server 24 with a central point of connectivity in a wireless network and always enabling connectivity necessary for tracking states of the system components. Additionally, detection and communication wireless access point 180 can provide a connection point between a wired and wireless network and the home occupant at remote locations.

In FIG. 11, the system components include control module 20, television 22, a media and detected data distributor 113, and a cable box 17. Other system components having external control interfaces such as cable or IR can be included, such that telephone means 12, interactive detector 122, control system 10, positioning unit 120, computer 16, camera 18, control server 24, monitor 28, a voice auditory/audio means 118, residential, commercial/industrial application software 26, and the like are interactively communicable through wired/wireless means.

The network illustrated in FIG. 11 also includes an infrared/serial bridge 128, having detection means, and in communication with the control module 20, control server 24. In an embodiment, Infrared/serial Bridge 128 complies with the IEEE 49.11(b) standard for wireless communications. Infrared/serial bridge 128 exchanges infrared signals with stand-alone system components, such as television 22, cable box 17 and media and detected data distributor 113 and also separates detection type by distinguishing a human body from other detections “U.S. Pat. No. 6,762,686.”

FIG. 12 illustrates another embodiment of server network control system 10, which includes a plurality of infrared/serial bridges 128(a)-128(e) for human body detection in homes with plurality rooms for enabling interactive communication. Each infrared/serial bridge 128(a)-128(e) interacts with one or more stand-alone components of the system such as fire alarms, control server 24, control module or the like. As shown, infrared/serial Bridge 128(a) interacts with television 22(a), cable box 17, and media and detected data distributor 113. Infrared/serial Bridge 128(b) interacts with a tuner 1104 or any type of proprietary Ethernet device. Infrared/serial Bridge 128(c) interacts with a residential.

FIG. 13 illustrates another embodiment of server network control system 10, which includes a smoke detector 138. Smoke detector 138 includes a network interface card 182 which enables smoke detector 138 to serve as yet another platform for control server 24, providing the control server with Home-PNA and/or wireless (e.g., IEEE 49.11) network connectivity. By taking advantage of the smoke detector's location and access to power lines, the control server can send data and/or control messages throughout the controlled environment either through a cable and a wireless connection or through the power line. Since most smoke detectors are presently hard-wired into the home or office power line, the smoke detector platform also provides always-on connectivity for control server 24. Another advantage of using a smoke detector as a detection platform for control server 24 is that smoke detectors can be ceiling/wall mounted to facilitate a greater communications range.

Control server 24 is one or plurality servers, with each server being one or plurality computers providing various shared resources with each other and to other system components. The shared resources include data for programs, web pages, databases and libraries; output devices, destination, such as, printers, plotters, display monitors and facsimile machines; communications devices, destination, such as modems and Internet access facilities; and other peripherals such as scanners, etc. The communications devices, destination can support wired or wireless communications, including satellite, terrestrial such as fiber optic, copper, coaxial, and the like, radio, microwave, free-space optics, and/or any other form or method of transmission.

In an embodiment, control server 24 is configured to support the standard Internet Protocol (IP) developed to govern communications over public and private Internet backbones. The protocol is defined in Internet Standard (STD) 5, Request for Comments (RFC) 101 (Internet Architecture Board). Control server 24 also supports transport-protocols, such as, Transmission Control Protocol (TCP), Home occupant Datagram Protocol (HODP), Real Time Transport Protocol (RTP) or Resource Reservation Protocol (RSVP). The transport protocols support various types of data transmission standards, such as File Transfer Protocol (FTP), Hypertext Transfer Protocol (HTTP), Simple Network Management Protocol (SNMP), Network Time Protocol (NTP), or the like to enable real time detection and communication.

Video controller 106 manages the exchange of video signals within system 10. Video controller 106 receives and/or distributes video signals for displays coupled to screens, for example, computer 16, television 22, monitor 28, control module 20, etc. Video controller 106 also interacts with the A/R components, such as, media and detected data archive 04, secondary control server 23, DSS box 15, cable box 17, media and detected data recognizer 06, media and detected data analyzer 08, network connection 90, etc. In embodiments, video controller 106 reads and/or writes to an internal storage medium that is designated for video in addition to or in lieu of the A/R components.

Accordingly, video controller 106 receives video signals from the A/R components and/or its internal storage medium and distributes them to other system components such as television 22, control module 20, etc. Video controller 106 can also receive a video stream from a source such as a network connection 90, television 22, media and detected data archive 04, etc. and store the stream in one of the A/R components such as media and detected data archive 04, media and detected data analyzer 08, etc. and/or its internal storage medium, for future viewing. For example, video controller 106 can query a web site such as “www.bet.com” to download a music video to be played and/or stored to a system component while also checking for ongoing security at a current bet show. To enable distribution over communications network 80 and/or Internet, video controller 106 provides MPEG encoding on the fly according to embodiments of the present invention. Video controller 106 is able to receive, encode, and distribute a media and detected data stream in real time or near term. In embodiments, network connection 90 enables video controller 106, or like components, to implement broadband Internet access for audio/video distribution of security data.

Another controller module is audio controller 108. Audio controller 108 manages the exchange of audio signals within system 10. Accordingly, audio controller 108 receives and/or distributes audio signals for one or more audio components, such as, for example, a voice auditory/audio means 118 or speakers coupled to a computer 16, television 22, monitor 28, control module 20, etc. Audio controller 108 also interacts with the A/R components such as the secondary control server 23, DSS box 15, cable box 17, media and detected data recognizer 06, media and detected data analyzer 08, network connection 90, etc. to receive audio/visual signals from the A/R components and distribute them to other system components such as a voice auditory/audio means 118 and a control module 20, etc. Additionally, audio controller 108 can receive an audio stream from a source such as network connection 90, television 22, media and detected data archive 04, etc. and store the stream in one of the A/R components such as media and detected data archive 04, media and detected data analyzer 08, etc. for future recall. In embodiments, audio controller 108 reads and/or writes to an internal storage medium that is designated for audio, and hence distributes audio to and from its internal storage medium. For example, audio controller 108 can query a web site like “MP3.com” to download a digital recording to be played and/or stored to a system component. In an embodiment, audio controller 108 encodes the audio stream to MPEG-3 format to produce near-CD quality in real time or near time. In another embodiment, audio controller 108 encodes the audio stream to produce CD quality audio in real time or near term.

Telephony controller 110 is another controller module within the control server 24. Telephony controller 110 manages the distribution of telecommunications from conventional telephone paths and/or television network in connection with a computer means such as communications network 80 and/or Internet, network connection 90, etc. In an embodiment, telephone means 12 is coupled to a conventional wired or wireless telephone path, such as POTS or PSTN. Telephone means 12 can also be coupled to a cellular or satellite communications path. A dedicated interface is provided to enable the cellular/satellite telephone means 12 to interact with system 10. Calls received or transmitted over the conventional path are also monitored and/or controlled by control server 24. As such, control server 24 is responsive to distributing detection and communication signals from the calls or detection environment to other system components. For example, control module 20 is one potential recipient component. Hence, a home occupant is able to directly operate control module 20 to place and/or receive calls indirectly via telephone means 12.

In another embodiment, telephone means 12 is coupled to a television network in connection with a computer means. Alternatively, a wired or wireless telephone that is coupled to computer 16 is capable of interacting with a television network in connection with a computer means. The television network in connection with a computer means is a LAN or WAN such as the Internet that is accessed via communications network 80 or network connection 90, or the system components such as telephone 102, computer 16 means, can have a dedicated link to a television network in connection with a computer means, such that the link is independent of communications network 80. In an embodiment, the telecommunications signals are formatted for VoIP or the like. Irrespective of the source of the television network in connection with a computer means, the telecommunications signals from the television network in connection with a computer means are monitored and/or controlled by control server 24. As discussed with reference to conventional telecommunications calls and security detection, control server 24 is responsive to distributing signals from the calls and detection media to other system components, such as, for example, control module 20.

In addition to answering, placing, and/or distributing detection and telecommunications calls and detection data, control server 24 is operable to perform other telephony functions. In an embodiment, control server 24 supports speed dialing and directs cable communication services. Telephone numbers are stored in a memory 200 such as one of the A/R components described with reference to FIG. 2 coupled to residential, commercial/industrial control server 24. In another embodiment, control server 24 is programmable to implement service blocking. Home occupant will be able to create a profile to block telephone and detection data calls from a designated number or family or numbers. In yet another embodiment, control server 24 logs inbound/outbound communication signals and/or enables redialing past and/or missed calls to security agencies and/or home occupant.

Control server 24 also includes messaging controller 112, which enables centralized storage of telephone calls received via telephony controller 110 and the like. Voice messages are written to a memory 200 such as is contained in one of the A/R components described with reference to FIG. 2 coupled to control server 24. Messaging controller 112 also permits messages including audio, video, and/or text to be created, stored, and/or retrieved within system

In other words a home occupant can operate one of the system components such as the control module 20, telephone means 12, a voice auditory/audio means 118, etc. to create a message for the same or another home occupant. Messaging controller 112 also enables control server 24 to interact with computer 16 or other system components to search and/or retrieve data from computer emails, instant messaging services, and/or notes, tasks, reminders, and/or events from personal calendars.

Control server 24 also includes file-sharing controller 114. File sharing controller 114 enables control server 24 to function as a central file server for all personal televisions in communications with system 10. File sharing controller 114 permits data to be stored and accessed by system components located within the homes/offices and residence that is hosting system 10. However, in an embodiment, devices, destination located outside of system 10 is able to store and/or retrieve data via file sharing controller 114. That is, if a static IP address is sustained by the ISP for system 10, a remote home occupant could log into control server 24 to retrieve and/or store data via file sharing controller 114.

Control module 20 is another controller module in communication with control server 24. Control module 20 manages access to the system components from external devices, destination and/or applications, and/or access to external devices, destination, applications, and/or web sites from the system components. The control module 20 provides a gateway to external networks, such as the global Internet, other private WANs, or the like. In an embodiment, control module 20 supports web proxies and is configurable to block designated web sites into control servers or per home occupant request. In another embodiment, control module is operable to track and/or record access/visits to control server and sites to the system network.

Control module 20 supports wired and/or wireless access to external networks, including cable and/or satellite ISPs. In an embodiment, control module 20 permits control server 24 to operate as a web server, provided the ISP is able to provide a static IP address.

Security controller 116 enables control server 24 to interact with and/or manage various security systems, including the communications to interactive detector 122 and cameras and communications security protocols for system 10. In an embodiment, security controller 116 controls and/or monitors feedback from system components that form a part of the security system. That is, a video camera 18 and voice auditory/audio means 118 and camera 18 can be captured and served to control module 20 or monitor 28. Motion sensors can also be placed within the homes/offices and residence or in external locations surrounding the homes/offices and residence. Feedback from the motion sensors can also be transmitted to security controller 116. In an embodiment, such feedback activates cameras 80 and/or voice auditory/audio means 118 within the vicinity. In another embodiment, such feedback activates security alarm or signals the home occupant's control module 20. To signal the home occupant, control module 20 can vibrate, ring, flash a message, or the like. Control systems coupled to camera 18 permits the security controller 116 to move and/or focus camera 18. In an embodiment, security controller 116 is operable to lock or unlock doors, windows, or entryways in response to home occupant input.

In an embodiment, security controller 116 interfaces with fire and safety control system within the home/office. As such, sensors feed into control server 24 and permit system 10

occupant to log in and monitor emergency situations. Alarms, sprinkler systems, and the like can be operated via control server 24 and/or control module 20.

A home occupant can be authorized via security controller 116 to log into control server 24 over the Internet from a remote location and receive live feeds from camera 18, archived feeds from camera 18, broadcasts from television 22 messages stored via messaging controller 112, data stored via file sharing controller 114, or the like.

Control server 24 is not limited to the functions depicted in the embodiment. Control server 24 can include other modules for controlling the operations and functions of the various system components for enabling home security monitoring and activation through a home occupant's remote-control commands. In an embodiment, control server 24 can set or synchronize a clock for one or more system components, including the A/R components. Control server 24 includes a real-time clock that can be set by a home occupant through a direct control module interface with control server 24 or through another system component, such as secondary control server. Alternatively, the real-time clock can be set via the Internet through network connection 90. Control server 24 uses its own real-time clock to set the clock of other system components by navigating the menu system of the respective system component. Since control server 24 tracks and monitors the state of the system components, control server 24 is programmable to navigate the menus of the system component to set the clock without interfering with the component's operations, such as when a television is on.

Instructions for navigating a system component are stored in a database or similar library coupled to control server 24. In other words, the input numbers for navigating the menus of a VCR or DVD distributor to set or program its internal clock can be memorized. The memorized numbers are associated with a set of IR codes, which are stored at control server 24. At the appropriate time, the IR codes are retrieved from the IR code database or library, and transmitted to the appropriate media and detected data analyzer 08. Upon receipt, the IR codes are executed to navigate the menus to set the clock. IR codes can also be selected to program media and detected data analyzer 08, to record select programs detection and the like.

In addition to setting the configuration of system components, control server 24 governs the addition and/or deletion of system components to server network control system 10. In an embodiment, an environment profile is established to track and monitor all devices, destination and/or applications within a specified environment of the controlled environment. A text-based or graphical home occupant interface enables a home occupant to specify the location or dimensions of an environment for monitoring. An environment can be one or more rooms or designated areas within a room. The present invention can also be used to control the operations and functions of system components located within the surrounding area of a home.

Once an environment is established, the home occupant can specify the system components that will governed the environment and enable communication with the control server 24. The system components are in automatic communication with the network 100. A system component announces its presence by broadcasting a detection control message on a continuous or periodically scheduled basis. Control server 24 receives the broadcast and adds the system component to the profile for that particular environment by extracting a detection type and properties for the system component from the detection message. The system component can be automatically interfaced with the environment profile. The home occupant can expressly accept the profile change, or ignore it thereby allowing the profile change to be automatically approved. With respect to updating pro-data, control server 24 can also explicitly enable a request through a broadcast mechanism that all system components in an environment identify themselves through.

The server network control system tracks and/or monitors the positions of various objects and system components in real time. When a home occupant migrates within the controlled environment that hosts system 10, the present invention can implement several protocols to enable detection within system 10 to determine a location of an intelligent object or the component and the location of any home occupant presence by enabling communications with the intelligent component. A control server 24 has a processor in communication with the intelligent component for enabling determination of the current location of the intelligent component, and sends instructions to reconfigure the intelligent component to control other system components within specified vicinity. When a control module 20 is determined to be located within a dining area and enabled, the control server 24 will then be allowed to control the control module 20 to enable controlling system components positioned in the dining area responsive for video recording and close-up shots.

Positioning devices are utilized in several embodiments for tracking and/or monitoring intelligent components. As described above one or more positioning units 120 are distributed throughout the controlled environment that hosts system 10. The positioning units 120 can be coupled to an intelligent component such as a control module 20, a voice auditory/audio means 118, telephone means 12, or located as a stand-alone device within the controlled environment.

In an embodiment, positioning unit 120 is part of a RF communications system. That is, a RF transponder interacts with a RF interrogator to communicate positioning information. The transponder is coupled to a system component and makes available identification information that uniquely identifies the system components and detection types. The transponder can make available other types of information, including an assigned location of the system component if the component is a stationary or infrequently moved device. Therefore, as described in further detail below, the transponder can be coupled to either the intelligent component or a positioning unit 120.

The transponder can be active or passive. An active transponder transmits a continuous or periodic signal containing the identification information. A passive transponder remains inactive and/or silent until it is activated by detection, an interrogator, or manually activated by a home occupant. Therefore, the system component can operate in a silent mode or active mode. In active mode, the position of the system component is being tracked and/or monitored in real time or near term. In silent mode, the current position of the system component is not known to system 10 with absolute certainty until the transponder is activated.

The interrogator is coupled to another system component and receives positioning information when it comes within the communications range of a transponder. The interrogator will automatically receive the positioning information from active transponder, or will activate a passive transponder to receive the positioning information.

The interaction between a transponder and an interrogator can be explained with reference to FIG. 4A and FIG. 4B. FIG. 4A illustrates an embodiment for positioning system components within system 10. A transponder 125 is coupled to control module 20, and an interrogator 135 is coupled to or embodied within positioning unit 120. When a home occupant 01 carrying control module 20 enters the vicinity of positioning unit 120, positioning unit 120 receives identification codes from control module 20. The identification codes include an identifier for the transmitting control module 20, or the like. In an embodiment, positioning unit 120 sends the identification codes to residential, commercial/industrial control server 24 for further processing. Positioning unit 120 can also send other identification codes or information with the identifier to the control module 20. In an embodiment, positioning unit 120 sends a vicinity identifier or the like data in response to detection of at least an object, wherein the object is responsible for the activation of devices in environments of the residential, commercial/industrial environment where positioning unit 120 is located. In another embodiment, control server 24 determines the vicinity identifier from an identifier assigned for the positioning unit 120.

FIG. 4B illustrates another embodiment for positioning a system component within system 10. As shown, transponder 125 is coupled to or embodied within positioning unit 120. Interrogator 135 is coupled to control module 20. Therefore as home occupant 01 carrying control modules 110 enters the vicinity of positioning unit 120 such as transponder 125, control module 20 receives identification codes from positioning unit 120 in response to any detection. The identification codes include an identifier for the transmitting positioning device 104, a vicinity identifier for the environment in which detection was enabled such as, floor, room, etc. of the controlled environment, or the like. In an embodiment, control module 20 processes the identification code to determine its location and/or sends the identification code to control server 24 responsive for enabling transmission or for archival purposes. In another embodiment, control module 20 sends the identification code to control server 24 to determine its location and for further processing. Again, control module 20 has been described by way of example. Other system components can also be coupled with an interrogator 135 and, thereby, configured to have other locations determined by embodiments of the present invention.

In an embodiment, transponder 125 is an electronic tag, beacon, controller, or the like. The electronic tag is characterized as having any shape or size, and is located on, or integrated within, the system component. The electronic tag includes a microprocessor 105 connected to enable communication with the communications circuitry that supports RF communications with other devices responsive for dialing other destinations. The microprocessor 105 is coupled to a memory 200 responsive for storing and communicating information such as identification information to control server 24, and transceiver responsive for exchanging information with the other devices to distant destination.

In an embodiment, transponder 125 has a dedicated microprocessor 105 for transmitting positioning information. In another embodiment, transponder 125 utilizes or shares the microprocessor 105 for the hosting system component such as the control module 20 to enable exchanging object positioning information. For example, the hosting system component would include an infrared port that is coupled to a microprocessor 105 and memory 200 located in the system component. The memory 200 includes the identification information and all related data. The microprocessor 105 interacts with the memory 200 and infrared port to support exchanges with interrogator 135. As such, the interaction among the microprocessor 105, memory 200 and infrared port serves as transponder 125 and indicative of responding to detection data.

Wireless communications between transponder 125 and interrogator 135 are supported by various interchangeable technologies. In an embodiment, the Bluetooth™ wireless technology is used to implement a short-range wireless interface between transponder 125 and interrogator 135.

In lieu of, or in addition to RF communications, and the incorporation of RFID chip for detection and for transmitting and receiving signal communication, positioning unit 120 in the embodiment further enables data collection using at least a bar code through a system. In other words, a bar code is disposed to at least a detection system's component and stores identification information that uniquely identifies the system component and location. As described with reference to a transponder, the bar code can store other types of information, including the assigned location of the system component if the component is a stationary device. A bar code scanner collects the identification information so that the information can be processed to determine the location of the system component.

Bar code data collection can also be described with reference to FIG. 4A and FIG. 4B. In other words, interrogator 135 is a bar code scanner and transponder 125 is a bar code according to embodiments of the present invention. Referring back to FIG. 4A, a bar code transponder 125 is disposed to control module 20 and a bar code scanner 126 is disposed to or embodied within positioning unit 120 having embedded sensors. As home occupant 01 carrying control module 20 enters the vicinity of positioning unit 120 such as a bar code scanner 126, the positioning unit 120 receives the identification codes containing an identifier for the control module 20. As described above with reference to an interrogator, the identification codes, with or without a vicinity identifier, are sent to control server 24 for further processing. Although control module 20 has been described by way of example, other system components can also be coupled with a bar code transponder 125 and, thereby, configured to have other locations determined by embodiments of the present invention.

Referring back to FIG. 4B, another embodiment for positioning system components with bar coding is illustrated. As shown, bar code transponder 125 is disposed to or embodied within positioning unit 120, and a bar code scanner 126 is disposed to control module 20. As home occupant 01 carrying control module 20 enters the vicinity of positioning unit 120 such as bar code transponder 125, control module 20 receives the identification codes containing an identifier for the transmitting positioning unit 120. As described above with reference to a transponder, the identification codes, in an embodiment, includes an identifier for the transmitting positioning device 104, a vicinity identifier for the environment of the residential, commercial/industrial environment, or the like. The identification codes, with or without a vicinity identifier, are processed by control module 20 to determine its location, and/or sent to control server 24 as seen in FIG. 1, for further processing. Although control module 20 has been described by way of example, other system components can also be coupled with a bar code scanner 126 and, thereby; configured to have other locations determined by embodiments of the present invention.

The utilization of RF and bar coding technologies represents alternative methodologies for detecting, tracking and/or monitoring the location of system components. As would be apparent to one skilled in the relevant art(s), other positioning technologies can also be implemented with the present invention. For example in larger scaled environments, the use of at least GPS receivers, cellular signals, and triangulation or the like is available alternatives.

In another embodiment, positioning means can be realized without the use of positioning unit 120. Control module 20, or the like is responsive for receiving and processing commands from the home occupant operating control means 111. The commands are manually and/or verbally entered into control means 111. Control module 20 processes the commands, or sends the commands to control server 24, to determine the location. For example, the home occupant can specify the location for example “living room,” and the control module 20 would be profiled to activate control devices to enable-data transmission to other destination within the living room, the home and external to the home.

In another embodiment, however, voice and/or manual commands can be entered into positioning unit 120 or the like. The home occupant would also enter an identifier for the intelligent component (e.g., control module 20), and position unit 14 would send control signals to control server 24, or the like, to update the location records of intelligent component.

As described above, the present invention supports various protocols for gathering detection data and location information. The present invention provides several methods and/or techniques for processing the location information to track and/or monitor the position or movement of various components of system 10. Referring to FIG. 5, FLOWCHART 100 represents the general operational flow of an embodiment of the present invention. More specifically, FLOWCHART 100 shows an example of a control flow for tracking and/or monitoring system components within a controlled environment.

Referring to FIG. 5, the control flow of FLOWCHART 100 begins at mode 01 and passes immediately to enable detected data to mode 03. At mode 03, an appropriate component of system 10 accesses locator codes that correspond to a system component such as intelligent component that is being tracked and/or monitored. Referring back to FIG. 1 and FIG. 2, the present invention can determine the current position of any of the aforementioned system components, including, but not limited to, telephone means 12, positioning unit 120, computer 16, camera 18, control module 20, television 22, control server 24, monitor 28, video camera 107, and a voice auditory/audio means 118, residential, commercial/industrial application software 26, media and detected data archive 04, secondary control server 23, DSS box 15, cable box 17, media and detected data recognizer 06, media and detected data analyzer 08, and/or other devices that would enable sharing data to other destinations and/or other device applications.

As described above, the present invention includes various embodiments for accessing locator codes and/or a vicinity identifier. For instance, in the described embodiment, a home occupant interacts with a text or graphical interface to manually enter the current location for an intelligent component. In another embodiment, a voice command interface enables the home occupant to enter voice commands for an intelligent component responsive for enabling

communicates the through devices in current and distant location indicative of enabling communication with intruders from remote locations.

In an embodiment, an intelligent component interacts with positioning unit 120 to access locator codes. Referring back to FIG. 4B, the intelligent component being at least a control module 20, is coupled to interrogator 135. Interrogator 135 polls positioning unit 120 for a vicinity identifier. The vicinity identifier includes an infrared sensor 06 having locator codes responsive for identifying the current location of detection activities and for identifying the location of home occupants when detection is enabled for both or all system components.

Referring back to FIG. 4A, interrogator 135 is integrated with positioning unit 120 and connected to the control module 20 to enable interactive communication with an intelligent component. The intelligent component representing at least a control module 20 is polled by interrogator 135 and in communication with plurality devices. As a result, interrogator 135 receives an identifier for the polled intelligent component to enable a locator code representing at least the vicinity where detection was enabled. The locator codes are then produced and transmitted by associating the identifier with the vicinity identifier for the interrogator 135.

Referring back to FIG. 5 at mode 06, the locator codes are sent to a command center for further positioning processing to enable data transmission to at least the control server 24. In an embodiment, the command center is control server 24. In another embodiment, the command center is the intelligent component representing at least a control module 20, computer 16, telephone, television, etc.

at mode 09, the locator codes are matched to an environment representing various levels of the home. The environment can be a specific floor, hallway, corridor, balcony, room, or the like monitored with sensors. The environment can further be a specific area within a floor, hallway, corridor, balcony, room, or the like and being watched by interactive detector 122. The environment can also be a specific area within an external perimeter of the offices and residence hosting system 10, or an adjoining or at least a standing shelter on the residential, commercial/industrial grounds.

At mode 12, the current environment is communicated to the intelligent component and/or stored in the records of control server 24 for future recall. After the system component has been positioned and its positioning data has been updated, the control flow ends as indicated at mode 13.

In an embodiment, the positioning information enables system 10 to command and/or control specific system components based on the current location of a home occupant interacting with system 10. This can be described with reference to FIG. 6. FLOWCHART 200, as illustrated in FIG. 6, represents the general operational flow of an embodiment of the present invention. More specifically, FLOWCHART 200 shows an example of a control flow for commanding and/or controlling system components based on a home occupant's current location. Referring to FIG. 6, the control flow of flowchart 200 begins at MODE 11 and passes through media links to detect data indicative of unwanted objects to enable MODE 03-09. As described with reference to FIG. 5 at MODE 03-09, locator codes enable system 10 to determine the current location or environment of a home occupant upon detection, and enabling the detectors to interactively enable communication with an intelligent component having at least a control module 20.

At MODE 12, an environment profile is accessed for the environment. The environment profile includes a listing of devices having links with distant destination and/or other device applications representing system components that receive commands and/or controls from control server 24 and/or control module 20.

At MODE 15, the environment profile is processed to present control options for the home occupant to review. The control options include the listing devices in communication with device destination and/or other device applications corresponding to the environment profile. As described with reference to FIG. 5, the positioning can be determined remotely at control server 24 or locally at the intelligent components such as cell phones, telephones, computers, portable wireless devices, control module 20, and the like. If detection is enabled and determined remotely, control server 24, for example, produces description of the detection through interactive communication with plurality devices having camera means and in wired/wireless communication with the control server. The control server 24 sends a home occupant detection data through interface means with at least a intelligent component and enable displaying the detection and control options on the intelligent component such as the control module 20 or another system component the home occupant is operating. If transmitted data is determined locally, at least the intelligent component retrieves the environment profile data to enable the home occupant to interface with the environments of the home to which detection was enabled and also with security agencies such as the fire department and the police department. The environment profile can be sent to the intelligent component on demand through wired/wireless means, or the intelligent component can be updated periodically with available environment data.

At mode 18, the home occupant operates the intelligent component such as at least a control module 20 to send a request to control a system component such as television 22, application software 26 and the like that are identified in the environment profile. The home occupant can send a request to control a function and/or an operation of a system component. The home occupant can send a request to alter the configuration or security profile for the component. Other control request can be sent as would be suggested by one skilled in the relevant art(s). At mode 21, the control request is executed by the designated component such as at least a television 22. The control request can be transmitted directly to the designated component, or indirectly to the designated component via control server 24. After the control request has been executed, the control flow ends as indicated by mode 95.

For example, if a home occupant is operating control module 20 and is determined by system 10 to be positioned in the living room, control module 20 would receive a home occupant interface signal responsive for controlling system components in the living room. One system component can include, for example, security monitor 28 that receives video input from camera 18 located at the television 22, the front door to the offices and residence homes, or embedded in the interactive detector 122 devices positioned in the various environments of the homes. The home occupant can interact with control module 20 to pan, tilt, or focus camera 18 on the television to display an image on television monitor 28, other monitors and hand held devices to display images of intruders standing at the front door hiding inside the house. Another system component can be television 22 in communication with the control module 20 for receiving home occupant interface signal and responsive for controlling the activation of interactive detector 122, the alarm volume levels for the detectors, and/or channel selections for enabling detection images to be transmitted through the television 22 to the control server 24.

The present invention supports various texts, graphical or verbal command interfaces for presenting the control options to a home occupant. FIG. 7 illustrates an embodiment of a home occupant interface 183 for presenting location-specific control options and for enabling detection data transmission. Home occupant interface 183 is produced on control module 20. However, as described herein, a home occupant can operate any of the other system components to send control demands, provided the system component is configured to produce interactive communication with home occupant interface 183 or the like.

Home occupant interface 183 includes a control options environment 184. Control options environment 184 identifies system components from an environment profile for a designated environment. In this example, the environment is a living room, a kitchen, a dinning room, a bed room, a basement, an office, or the like. System components identified in the environment profile for living room include television 22 and a voice auditory/audio means 118. Component controls 185 a-185 b enables a home occupant to send control demands to a corresponding system component. Component control 185 a corresponds to television 22. Component control 185 b corresponds to a voice auditory/audio means 118. Additional component controls 185 a-185 b can be included to send control demands to other system components profiled for a particular environment.

The environment, specified by control options environment 184, can be determined by the positioning embodiments described above, or the environment can be home occupant-specified regardless of the current location of the home occupant's control module 20. The environment is home occupant-specified region by activating the environment interactive detector 122,121.

Messaging interactive detector 122,123 enables the home occupant to interact with messaging controller 112 described with reference to FIG. 3. Therefore, the home occupant is able to check detection emails, voice mails, intra-residential, commercial/industrial messages, or the like.

Media and detected data viewer 210 is linked with the control server and enables the home occupant to view media and detected data from the television and other system component. For example, the home occupant can interact with component control 185 a to view a television program that is currently being broadcast on television 22 while the television 22 is also responsive for monitoring the home and for enabling communication when detection is enabled. That is, sensors are embedded inside the television 22, and the sensors enable interactive communication with the video camera embedded inside the television for enabling detected image transmission. The home occupant can also interact with component control 185 b to receive audio from a voice auditory/audio means 118.

Although media and detected data viewer 210 is shown as a video or multimedia and detected data distributor, media and detected data viewer 210 also allows audio signals to be received without video. Media and detected data viewer 210 can also be a web browser, or software application for word processing, video games, or the like. Therefore, the home occupant can interact with control options environment 184 and environment interactive detector 122,121 to receive text, audio, video, or media and detected data and/or multimedia and detected data from other system components from any location within the residential, commercial/industrial environment hosting system 10.

The present invention enables a home occupant to operate control module 20 to command and/or control other system components. In an embodiment, control module 20 only permits the home occupant to control system components within the vicinity of control module 20 environments. In another embodiment, control module 20 provides the option of controlling system components in another environment.

In embodiments, control of the various system components is based on preset data established and assigned to various types of detection for the home occupant. The data can be generic for all home occupants and/or specifically configured specifically for home occupant use. If configured for a specific home occupant, the present invention utilizes various protocols to identify or authenticate a specific home occupant and execute the profile established for the home occupant. In an embodiment, a home occupant detection type and/or password is entered into a system component such as control module 20, etc. The password can be expressed by at least a verbal command, text, object, mega-pixel resolution having optical/digital zoom, or the like. In another embodiment, biometrics is collected by a system component. As such, retinal, iris, facial, palm, fingerprint, and/or voice recognition technologies, or the like are implemented to identify and/or authenticate a home occupant. In another embodiment, a home occupant card is read by a system component such as the control module 20. Other home occupant identification and/or authentication techniques can be used to identify and/or authenticate a home occupant. The present invention permits the home occupant to alter the profile, as appropriate. The identification and/or authentication techniques, described above, prevent other home occupants from altering or deleting the home occupant profile after it has been established.

In embodiments, the present invention enables a home occupant to establish a profile to store a favorite setting for the system components. For example, a favorite setting can be established for television programming, audio/video recordings, room temperature control, clock alarms, light/dimmer settings, web sites, news broadcasts, or the like.

In embodiments, the home occupant can establish a profile to create a checklist. A sequence of graphic images or photographs can be prepared and/or stored for transmission or playback on, for example, monitors 116 or computer 16. A checklist of other forms or media and detected data and/or multimedia and detected data can also be created according to embodiments of the present invention, as would be apparent to one skilled in the relevant art(s).

In embodiments, a profile can be created to establish a security protocol for the system components. For example, a profile can be created to block certain content from being accessed by non-designated home occupants. Non-adult home occupants, for instance, can be prevented from accessing designated television channels, web sites, areas such as, lockable rooms that store the codes to activate and/or deactivate the detection system.

In embodiments, the present invention enables a single home occupant to establish multiple data. Each of the multiple data can be tailored for context-sensitive activity. For instance, a home occupant can create a profile for security monitoring while enjoying evening entertainment, and the security monitoring includes without limitation, audio/video detection and presentations to a control server, security access warnings from interactive detector 122 or the like. A home occupant can also establish multiple data for use with other individuals. For example, a home occupant can have a profile with security controls set to block certain televisions programming and enable activation of the camera for communications with web sites, audio recordings, or the like when in the company of minors. However, when in the company of adults, the home occupant can recall another profile with more liberal security settings.

As such, the present invention enables various system components through the control module 20 to be home occupant awareness in addition to being location awareness. Thus for example, control module 20 can be customized per home occupant based on the aforementioned home occupant data. In embodiments, the home occupant awareness functionality permits system 10 to implement watch-me system controls. For instance, “watch-me” video is implemented to transfer a selected video detection to various displays throughout the controlled environment. The home occupant would operate, for example, control module 20 to select a video detection captured by the television video, DVD recording, or the like. The video production can be presented on control module 20 e.g., media and detected data viewer 210 described with reference to FIG. 7. As the home occupant migrates from room to room within the controlled environment, system 10 tracks control module 20 and retrieves environment profile for each environment. Therefore, as the home occupant enters a new environment or room, a monitor 28 or television 22 located in the room will automatically start to display the video production of the occupant selected by control module 20.

Similarly, “watch-me” audio can be implemented by the present invention. As such, the home occupant can operate, for example, control module 20 to select an audio production through CD recording or radio broadcast or the like. As the home occupant migrates from room to room, the positioning techniques of the present invention, which includes body heat sensors as members of the interactive detector 122, enable system 10 to transfer the audio production to the audio/video clients 118, such as the fire department and the police department, enabling the clients 118 to view first hand the situation and magnitude of the environment through a monitors 116 or the like that are located in the vicinity of the clients control module 20.

“Watch-me” lighting is another exemplary implementation of the present invention. As a home occupant, positioning or carrying control module 20 to enter or leave a room enables system 10 sends commands enabled based on the profile settings.

In an embodiment, one or more control microprocessor 105 enabling communication is established to control the operations and/or functions of the system components. A control microprocessor 105 includes a set of commands that, when executed, enables control server 24 to control multiple operations and/or functions of one or more system components. The control microprocessor 105 s enable set of commands to be associated with control microprocessor 105 detection data storage for future recall and execution.

A home occupant can define a control microprocessor 105 operation by operating control module 20, computer 16, or a home occupant interface in communications with control server 24. In an embodiment, a graphical home occupant interface can be implemented to enable a home occupant to define a new control microprocessor 105. FIG. 9 provides an example for defining control microprocessor 105 s according to an embodiment of the present invention. Flowchart 900 shows an example of a control flow for defining control microprocessor 105 s to watch the entire section or regions of the home and/or office.

Referring to FIG. 9, the control flow of flowchart 400 begins at mode 31. When the home occupant triggers a record-microprocessor 105 s command to distinguish the microprocessor 105 s communication and recording mode from normal system operations of cameras, detection is enabled at all environment. At mode 33, the home occupant operates one of the aforementioned devices to enable data transmission to other destination such as client the control module 20, computer 16, interactive detector 122 or a home occupant interface through communication with control server 24 indicative of viewing selected room containing and/or having the system component such as television 22, monitor 28, etc. responsive for enabling the home occupant to use the said components to view the detection environment and images.

At mode 36, the environment profile for the selected room is recalled. As discussed above, an environment profile identifies all system components located in a designated environment. In an embodiment, the environment data are stored at control server 24, which retrieves and makes the appropriate environment profile available to the home occupant.

At mode 39, the home occupant reviews the environment profile and selects a viewing system component such as a handheld monitor or a television 22. The home occupant also specifies the video input responsive for enabling a DVD source recording. The home occupant can specify any desired settings, including but not limited to making adjustments such as zoom, contrast, brightness, and the like.

At mode 42, the home occupant specifies the desired audio settings. In an embodiment, the home occupant set the volume level for the alarms and viewing system component such as television 22. In another embodiment, the home occupant selects external speakers for broadcasting when detection is enabled, such as a voice auditory/audio means 118 to be used in addition to, or in lieu of, the internal speakers for the viewing system component.

At mode 45, the home occupant selects the desired device to activate detection such as DVD, cable box, interactive detector 122 and the like in communication with the media and detected data recognizer 06. Alternatively, if a DVD distributor such as the media and detected data analyzer 08 are located in the same room with the selected viewing system component such as at least a television 22, the home occupant can instruct media and detected data analyzer 08 to enable activation of detection and image loading.

At mode 51, the control commands for executing the specifications for television 22, a voice auditory/audio means 118 (if selected), media and detected data analyzer 08 (or media and detected data recognizer 06), and lighting application software 26 are collectively associated with a

control microprocessor 105.

At mode 58, the home occupant saves the control microprocessor 105 s and gives it an activation code for enabling detection data, such as “sending images.” In an embodiment using control module 20 to activate microprocessor 105 s for “sending image,” communication with the home occupant can associate the microprocessor 105 s to a specific microprocessor 105 buttons or icon. Therefore, when the home occupant activates the “sending image” microprocessor 105 s button, all of the associated commands for implementing the home occupant's pre-specified selections are recalled and executed, so that television 22 is ready to communicate the desired request to control server 24. After the control microprocessor 105 s are activated and data saved, it is then ready for transmission and the control flow ends as indicated at mode 45.

In an embodiment, the commands associated with specific control microprocessor 105 s are stored at control server 24, or in a database or library affiliated with control server 24 or the media % and detected data archive 04. Therefore, in an embodiment using control module 20 to execute a control microprocessor 105, control module 20 enables a home occupant to associate other control microprocessor 105 s with a control microprocessor 105 s button or icon. When executed, the control microprocessor 105 s button transmits a generic command to control server 24. Control server 24, in turn, retrieves the set of commands associated with the generic command, and transmits the set of commands to the appropriate system components for execution. In other words, the present invention enables a mobile device, such as control module 20, to transmit a single high-level request to a centralized command center, such as control server 24. Control server 24 interprets the single request according to its environment such as the home, rooms, and location of other rooms and finds the corresponding sequence of commands that needs to be transmitted over communications network 80 and/or Internet, which includes wireless or power-line communications.

Alternatively, according to an embodiment of the present invention, the control microprocessor 105 is enabled automatically by the control server 24 based on the particular devices in which they are implemented on, or the destination means or existing interactive detector 122 in a selected room or environment. These devices are either known by the control server through stored room data or as detected in real time by the control server as the room profile is created. For example, if the control server detects that a room such as the living room has a DVD distributor and a TV, the control server will automatically build a basic “security watch” microprocessor 105 s comparable to the microprocessor 105 s described above, which can be further customized by the home occupant.

FIG. 10 illustrates an example for activating the control microprocessor 105 s according to an embodiment of the present invention. Flowchart 1000 shows a control flow for activating the control microprocessor 105 s of flowchart 900, which pertains to enabling security monitoring while watching a movie or enabling recording on a TV, DVD, etc.

Referring to FIG. 10, the control flow of flowchart 1000 begins at mode 61 and passes immediately to detection mode 63. At mode 63, the home occupant activates the “security watch” the control microprocessor 105 s as defined in mode 41-45.

FIG. 10 is a detailed block diagram of the audio/video (A/V) modulator 80 connected to the audio/video source 49 and television 22 media and detected data components of the interactive detector 122 of FIG. 1. The downstream network signal is enabled on line 200 from the wall plate connector 37 and received at the modulator's coaxial cable connector 201 to enable signal conduction through line 62 to a high pass frequency filter 204. The high pass frequency filter is referred to as RF modulated signal filter, and low pass frequency filters 78. The filters 204, 206 are substantially similar to high pass filters 67, 68 and low pass filters 69, 70 described herein with respect to FIGS. 3, 4, respectively. This high pass filters separate the received RF broadcast television signals and RF modulated video signals onto line 90, and the low frequency signals, including the un-modulated digital signals and electrical command signals, onto line 110.

The downstream broadcast signals on line 90 are presented through a BALUM 212 through line 114 to the A/V modulator's media and detected data signal output 216. The media and detected data signal output is connected by a coaxial cable 217 to the television 22. This media and detected data signal is presented on lines 90 back through the high pass frequency filter 204 to the coaxial connector 201 and to the control module 22, as seen in FIG. 1. The downstream low frequency digital signals from the low pass filters 78 on line 10 are separated by low pass filters 79 and high pass filter 238 respectively. The signal is then transmitted into 0-2.5 MHz data and information band signal on line 14 and the 2.5-5.0 MHz command and control band signal onto lines 8.

The low pass and high pass filters 236, 238 are substantially identical to the low pass and high pass filters 140, 142 of the Control server signal modulator, which are shown in preferred embodiments in FIGS. 6, 7. As stated herein with respect to the Control server signal modulator of FIG. 5, these are serial digital bit signals transmitted in serial digital form, without signal modulation, and they are transmitted through the network conductors in shared mode with the RF broadcast services signals. In a best mode embodiment the signal bit speed is substantially equal to 1.0 Mbps.

The A/V modulator 80 processes the network 2.5-5.0 MHz command and control band signals, i.e., the IR band in substantially the same manner as the Control server signal modulator of FIG. 5. As with the modulator/demodulator 188 of FIG. 5, the modulator/demodulator 140 frequency modulates the converted signal content at a preferred modulation frequency of substantially 3.0 Mhz. However, as stated herein, the modulation frequency may be any selected frequency within the command and control band 8.25-5.0 Mhz.

The modulated IR signal is presented through line 142 and back flowed through filters 68 to the line 6, where it is combined with the upstream data and information band signal from the filter 236. The combined low frequency signals are then back flowed through filters 78 to the coax connector 201 and combined with the RF modulated media and detected data signals and coupled through the communication port 134 as seen in FIG. 1, to the control module 22. The downstream command and control band signal is passed through low pass filters 78 and high pass filters 68 to the modulator/demodulator 140, which demodulates the signal and passes it to the IR/IrDA bridge device 148. The bridge then reformats the payload into an IR frame format and passes it to the IR emitter portion 176, 180 as seen in FIG. 6A, 6B of the IR emitter-detector combination transceiver 244. The IR emitter broadcasts the signal into the rooms, the home occupant's PC, and the security agencies PC's. This includes the CATV and other broadcast source signals received at the control module connector 42 from the line 1 shown in FIG. 1.

As shown in FIG. 11, each of the network ports is coupled through associated control module impedance matching networks 270-274, each connected between the control module signal bus 78A and the individual output ports 24-28. This signal path length is preferably less than a quarter wavelength of the network's highest frequency signal to prevent signal reflections occurring at an un-terminated port at the network's highest operating frequencies. These reflections may cause signal interference with both the broadband and broadcasting signal frequencies. In the present embodiment, with the CATV broadcast signal frequencies approaching 1 Gigahertz or at or about 900 Mhz, the quarter wavelength of a 1 Ghz signal is approximately 1.3 inches.

At mode 66, the set of commands associated with the “security watch” control microprocessor 105 s is recalled from other storage locations. The set of commands includes the home occupant-predefined specifications for controlling the functions and/or operations of the specified system components. In this example, the set of commands associated with the “security watch” control microprocessor 105 s include commands for altering application software 26 and responsive for activating media and detected data recognizer 06 and/or media and detected data analyzer 08, and activating television 22. If the home occupant desires to listen to the movie on a home stereo speaker system, the set of commands would also include commands for activating the appropriate audio system component such as a voice auditory/audio means 118.

In an embodiment using control module 20 to activate the control microprocessor 105 enables control module 20 to transmit a generic command that is associated with the “security watch” control microprocessor 105. The generic command is sent to control server 24, which recalls the set of commands associated with the generic command for the “security watch” control microprocessor 105.

At mode 69, the room and system components such as television 22, media and detected data recognizer 06 or media and detected data analyzer 08, lighting application software 26, a voice auditory/audio means 118 are identified from the set of commands. In the example described with reference to FIG. 9, the room is specified in the control microprocessor 105. However, in another embodiment, the control microprocessor 105, itself, does not need to be room specific. As discussed above, the present invention includes methodologies and/or techniques for tracking the location of a home occupant or controller device 110. Therefore, the home occupant can request to activate control microprocessor 105 s such as the “security watch” control microprocessor 105 to watch or enable security in any room the home occupant is currently located. As such, control server 24 would designate the home occupant's current location as being the room for implementing the control microprocessor 105. Likewise, control server 24 can retrieve the room profile for the home occupant's current location and identify the viewing components, media and detected data distributor, and lighting components that are located in the designated room.

At mode 72, a device for accessing permission is validated for each system component identified at mode 69. As discussed above, restrictions on operating various system components can be established and policed by security controller 116 while in communication with other security agencies. Accordingly, the present invention provides methodologies and/or techniques for identifying or authenticating the home occupant that is requesting the “security watch” control microprocessor 105, as well as for determining if the home occupant is authorized to operate the system components designated in the control microprocessor 105. If the home occupant is determined to lack authorization for accessing the designated system components, a message can be sent to inform the home occupant that access has been blocked indicative of lack of payment.

At mode 75, the present invention determines which commands are associated with each system component identified at mode 69. For example, the control commands for specifying the viewer settings are queued for television 22. In an embodiment, control server 24 apportions the component-specific commands for each system component. The component-specific commands are encoded and sent to the designated system component via the appropriate protocol. Control server 24 also updates its records for tracking the state of each system component.

At mode 68, each system component receives and executes the component-specific commands.

As such, the application software 26 enables interactive communication with detectors in the specified rooms and with the specified television 22 turned-on and configured as predefined, and the specified DVD distributor in communication with media and detected data recognizer 06 or media and detected data analyzer 08. Depending on the speaker options specified in the control microprocessor 105, audio 118 is also activated and waits to receive audio feed from the other components or interactive detector 122.

At mode 61, a control screen is sent to the home occupant interface to activate the control microprocessor 105. If control module 20 is used, the control screen is presented on the display to designate that the control microprocessor 105 s to ensure that the control microprocessor 105 s have been properly executed and other interactive devices are ready to commence monitoring, detecting, and communicating, if this option is selected. Afterwards, the control flow ends as indicated at mode 75.

FIGS. 1-7 are illustrations allowing an explanation of the present invention. It should be understood that embodiments of the present invention could be implemented in hardware, firmware, software, or a combination thereof. In such an embodiment, the various components and mode would be implemented in hardware, firmware, and/or software to perform the functions of the present invention. That is, the same piece of hardware, firmware, or module of software could perform one or more of the illustrated blocks such as components or mode to enable security watch.

Additionally, the present invention can be implemented in one or more computer systems, interactive detector 122, cable boxes for enabling security watch, or other processing systems, capable of carrying out the functionality described herein. Referring to FIG. 8, an example computer system 16 useful in implementing the present invention is shown. Various embodiments are described in terms of this exemplary computer system 16. The description makes it apparent to a person skilled in the relevant art(s) to implement the invention using other computer systems and/or computer architectures. The computer system 16 includes at least one by more processors, such as processor 56. Processor 56 can be a special purpose or general purposes digital signal processor. The processor 56 is connected to a communication

infrastructure 57 such as a communication bus, crossover bar, or network.

The control server 24 can represent a computer system 16, which further include a display interface 49 that forwards graphics, text, and other data from the communication infrastructure 57 or from a frame buffer responsive for enabling display on the display unit 830.

Computer system 16 also includes at least a primary memory 200,220, preferably random access memory 200 “RAM”, and at least a secondary memory 200,230. The secondary memory 200,230 includes a hard disk drive 64 and/or a removable storage drive 221 representing at least a floppy disk drive, a magnetic tape drive, an optical disk drive, a zip drive, responsive for storing and retrieving detection data and for enabling transmitting all detected data to at least an input source for reviewing selection. The removable storage drive 221 reads from and/or writes to a removable storage unit 231 in a well-known manner. Removable storage unit 231 represents a floppy disk, magnetic tape, optical disk, etc. which is read by and written to removable storage drive 221. As will be appreciated, the removable storage unit 231 includes a computer usable storage medium having stored therein computer software such as programs or other instructions and/or data for enabling effective security watch, detection, and communication within at least a localized vicinity.

In an alternative embodiment, secondary memory 200,230 includes other similar means for allowing programmed interactive high definition televisions or other instructions to be loaded into computer system 16. Such means include, for example, a removable storage unit 232 and an interface 233. Examples of such means include a program cartridge and cartridge interface such as that found in video games and other devices, for enabling security watch to destinations internal to the locations of the interactive detector 122. A removable memory 200 chips such as, an EPROM or PROM) is seen associated to at least a socket and other removable storage units 232 and interfaces 233, which allow software and data to be transferred from the removable storage unit 232 to computer system 16.

Computer system 16 can also include a communications interface 61. Communications interface 61 allows software and/or data to be transferred between computer system 16 and external devices. Examples of communications interface 61 include a wired/wireless modem, a network interface such as an Ethernet card, a communications port, a PCMCIA slot and card, etc. Software and data transferred via communications interface 61 are in the form of signals 62 which can be transmitted through electronic means, electromagnetic means, optical or other signals transmission means capable of being received by communications interface 61. These signals 62 are provided to communications interface 61 via a communications path such as TV channels 63. Communications path 63 carries signals 62 and can be implemented using wired/wireless or cable, fiber optics, a phone line, a cellular phone link, an RF link, free-space optics, and other communications channels.

In this document, the terms “programmed interactive high definition television medium” and “computer usable medium” are used to generally refer to security media and detected data transmission to devices such as removable storage unit 231, removable storage unit 232, a hard disk installed in hard disk drive 64, and signals 62. These programmed interactive high definition television products

means for providing software to computer system 16. The inventiion, in an embodiment, is directed to such programmed interactive high definition television products responsive for enabling security watch and for enabling data transmission to at least a device responsive for enabling Internet communication.

Programmed interactive high definition televisions, also called computer control logic or computer readable program, and are in communication with detection coding means stored in main memory 200,220 and/or secondary memory 200,230. Programmed interactive high definition television also receives detection and communication signals via communications interface 61. Such programmed interactive high definition televisions, when executed, enable the computer system 16 to implement the present invention as discussed herein. In particular, the programmed interactive high definition televisions, when executed, enable the processor 56 to implement the processes of monitoring and detecting at least a foreign object. The monitoring and detection method(s) are implemented using residential, commercial/industrial control server 24, control module 20, computer 16; and/or other system components for system 10 as described above, such as methods 500 and/or 600. Accordingly, the programmed interactive high definition television represents controllers for the server and computer system 16.

In an embodiment where the invention is implemented using software, the software can be stored in a programmed interactive high definition television product and/or loaded into computer system 16 using removable storage drives 221, hard drive 64 or communications interface 61. The control logic is at least software responsive for controlling the interactive detector 122 and other elements of the invention. The control logic, when executed by the processor 56, causes the processor 56 to perform the functions of monitoring, detecting, communicating, and transmitting detection data as described herein.

In another embodiment, the invention is implemented primarily using hardware, for example, hardware components such as application specific integrated circuits (ASICs) is an implementation of the hardware state machine responsive for performing the functions described herein for enabling security monitoring, detection, and communication. In yet another embodiment, the invention is implemented using a combination of both hardware and software.

While various embodiments of the present invention have been described above, it should be understood that they have been presented by way of example, and not limitation. It will be apparent to persons skilled in the relevant art(s) that various changes in form and detail can be made therein without departing from the spirit and scope of the invention. However, as previously discussed, it should be understood that the method, system, and programmed interactive high definition television product for security monitoring, detection, and communication as per the present invention should not be limited to a residential, commercial/industrial environment. The present invention is implemented in other types of environments having a central processing system such as the control server 24, responsive for enabling distribution of media and detected data and for sending command and/or control signals to plurality of devices in various destination and/or applications dispersed throughout a designated environment. In addition to offices and residence, the designated environment includes, but is not limited to, homes, apartment, office complexes, suite of small offices, production studios, warehouses, entertainment arenas, health care facilities, hotels, vacation resorts, or the like.

The present invention discloses interactive high definition television for enabling security monitoring, detection, and signal distribution through a control server, which provides plurality location for image transfer, telephone/audio communication, and security video application for entrances and other distribution throughout the home. Input services provided to each of connectors 44, 42 are electrically connected to module connectors 45, 52, 54 positioned within a central environment 53. Each module connector 44, 52, 54 is also electrically connected to a respective output connector 46, 48, 50. The module receiving section 47 corresponds with the module connector 45 and the output connector 46. Likewise, the module receiving section 49 corresponds with the module connector 52 and the output connector 48. This data line module 70 has a circuit board 74 positioned within a housing 78. This data module 70 is electrically configured to pass detection data signals from the first input connector 42 through the module connector 45, to the mating connector 72, and to the receptacle 73. The telephone line module 80 is configured to pass a selected detection through a telephone line to enable signal transfer from the input connectors 44, 42 through a selected module connector 45, 52, 54 to a selected output connector 46, 48, 50. The video module 106 is configured like the data line module 70 to pass a selected detection images through the video line from the input connector 44 to a module connector 45, 52, 54, and/or through the mating connector 72 and then to the electrical connectors 001 positioned on the front face 000 of the module 106. These electrical connectors 001 are preferably RCA jack type connectors however; other suitable connectors for passing video signals could alternatively be utilized on the front face 000 of the video module 106. The video module is configured to convert and/or transmit detected objects through video signals and therefore may include active components comprising tuner circuits, filtering circuits, or other video circuits. The video signal is received at the input connector from one of the connectors 001 on the front face 000 of the video module 106 within the distribution panel 400. Second output connectors 002 serve to connect detection output 106 to cables within the distribution network to rooms in the monitoring premises. Video signals may flow bi-directional through this circuit arrangement. Distribution through the premises may be accomplished by utilizing unshielded twisted pair cable, coaxial cable or other suitable video signal conductors. Additionally, a data distribution panel 200 is similarly joined to the distribution panel 400. The detection data distribution panel 200 is preferably a hub or other suitable data distribution device for a data network. The data distribution device is connectable to the receptacle 73 of a data line module 70 to facilitate bidirectional data communications between the data service input at a hub or other suitable data distribution device and the rooms of promises. This circuit extends first from the hub then through the cable to a desired data line module 70, then through a selected module connector 45, 52, and 54 to a selected output connector 46, 48, 50.

Electronic image sensors are embedded in the interactive detector 122, the interactive TV, DVD system, cable box system, computer system and the like, and typically comprised of mega-pixel resolution with optical/digital zoom arrays of a large number of very small light detectors, together called “mega-pixel resolution with optical/digital zoom arrays”. Electronic cameras comprise imaging components to produce an optical image of an emergency scene onto the mega-pixel resolution with optical/digital zoom array. The electronic image sensors convert the optical image detected into a set of electronic signals. The most popular electronic image sensors utilize arrays of CCD detectors for converting light into electrical signals. CMOS sensors have multiple transistors within each mega-pixel resolution with optical/digital zooms in addition to circuitry associated with each mega-pixel resolution with optical/digital zoom cell, CMOS sensors have other digital and analog signal processing circuitry, such as sample-and-hold amplifiers, analog-to-digital converters and digital signal processing logic circuitry, all integrated as a monolithic device for enabling object detection. In a preferred embodiment the sensor is a 0.3 mega-pixel resolution with optical/digital zoom of 3.2 mm.times.2.4 mm, 640.times.480 array of 5-micron square mega-pixel resolution with optical/digital zooms, which is compatible with a lens of 1/4.5 inch optical format. In preferred embodiments all of the camera circuits are incorporated on or in a single crystalline substrate along with the sensor mega-pixel resolution with optical/digital zoom circuits. High volume production costs for the above 0.3 mega-pixel resolution with optical/digital zoom camera are projected to be less than $8 per camera.

FIG. 3A is a partial cross-sectional diagram illustrating mega-pixel resolution with optical/digital zoom cell isolation for detection architecture designed for at least five mega-pixel resolutions with optical/digital zooms including sensors array utilizing principals of detection for the present invention.

The interactive television and the interactive detector 122 have single Chip Camera with Photo-isolation means in conduction with the Active Mega-pixel resolution having optical/digital zoom. Sensor A seen in the preferred embodiment of the present invention is a single chip camera with a photocell sensor including photo-isolation means consisting of a photodiode array. The photodiode array consisting of photoconductive layers on top of an active array of CMOS circuits is responsive for enabling monitoring, sensing, detecting, and communicating.

The sensor section is implemented with a photoconductor on active mega-pixel resolution with optical/digital zoom array having readout circuitry, readout timing/control circuitry, sensor timing/control circuitry and analog-to-digital conversion circuitry. The sensor includes:

-   -   a) a CMOS-based mega-pixel resolution with optical/digital zoom         array comprising at least 640.times.480 charge collectors and         640.times.480 CMOS mega-pixel resolution with optical/digital         zoom circuits. In other preferred embodiment, as shown in FIG. 2         additional MOS or CMOS circuits for converting the charges into         electrical signal responsive for amplifying the signals, for         converting analog signal into digital signal and for enabling         digital signal processing, which are provided on the same         crystalline substrate with embedded detection sensors utilized         for the collection of the charges. The data out of the sensor         section 100 is in digital form and with a mega-pixel resolution         with optical/digital zoom-sequential stream for imaging object         reflectance within the monitoring environment.     -   b) CMOS readout circuit in connection with the sensors and         interactive detector 122. The sensor includes the mega-pixel         resolution with optical/digital zoom array 300 and readout and         timing/control circuitry 104. FIG. 3A is a drawing showing the         layered structure of a 5 mega-pixel resolution having         optical/digital zoom section of the mega-pixel resolution with         optical/digital zoom array. Two of the four mega-pixel         resolutions with optical/digital zooms are coated with color         filters of peak transmission with at least 550 nm. They are         referred as “Green mega-pixel resolution with optical/digital         zooms”. One mega-pixel resolution with optical/digital zoom is         coated with color filter with peak at 450 nm “Blue mega-pixel         resolution with         optical/digital zoom” and one with filter peaked at 630 nm “Red         mega-pixel resolution with optical/digital zoom.” Just below the         electrodes 116 are CMOS mega-pixel resolution with         optical/digital zoom circuits 118. The components of mega-pixel         resolution with optical/digital zoom circuits 118 are described         by reference to FIG. 3B. The CMOS mega-pixel resolution with         optical/digital zoom circuits 118 utilizes at least three         transistors 310,312 and 314. Mega-pixel resolution with         optical/digital zoom circuit 118 in connection with the         interactive television includes collection electrode 306,         collection capacitor 308, source follower buffer 316, selection         transistor 314, and reset transistor 310 for enabling         monitoring, sensing, detecting, and for enabling communication.     -   c. The control signals and parameters provided to the imaging         object reflectance spectrum enables the image manipulation         circuits 106 b to make certain corrective changes to the image         data before outputting the data from the camera. The image         manipulation circuits 106 b receive the image data from the         environmental analyzer and, with consideration to the control         signals received from the control module, provides an output         image data signal in which the image data is optimized to         parameters based on the control algorithm. In these circuits,         mega-pixel resolution with optical/digital zoom-by-mega-pixel         resolution with optical/digital zoom image data is processed so         each mega-pixel resolution with optical/digital zoom is         represented by three color-primaries. The image manipulation         circuits provide color interpolation among each mega-pixel         resolution with optical/digital zoom and adjacent mega-pixel         resolution with optical/digital zooms with color filters of the         same kind so each mega-pixel resolution with optical/digital         zoom can be represented by three color components.

Input and output interface circuits 183 receive data from the communication protocol circuits 146 and convert them into the electrical signals that can be detected and recognized by the down-stream device. Since the sensor signal is directly proportional to the light sensed in each mega-pixel resolution with optical/digital zoom, one can calibrate the camera to have a nominal signal under desirable light. To bring the electrical signal back to nominal level, the mega-pixel resolution with optical/digital zoom exposure time to light and/or the signal amplification factor in sensor output, enabling the image manipulation module to be automatically adjusted. Since the sensor has mega-pixel resolution with optical/digital zooms covered with primary color filters, one can then determine the relative intensity of the light source from the image data. The number of mega-pixel resolution with optical/digital zooms could be increased or decreased from 0.3 mega-pixel resolution with optical/digital zooms almost without limit.

The present invention further relates to detection signal networks, and more particularly to detection signal networks for interconnecting multi-media and detected data devices with home occupants and security agencies. The current CEBus Standard installation guide for home networks specifies installation of a central distribution box such as control server 114, which receives all of the detection network signals and enables connection with the home occupant and other security agencies both internal and external. External signals include radio frequency (RF) broadband signals from CATV, satellite dishes, cable signals, and antenna for receiving broadcast signals such as RF broadcast signals, as well as DOCSIS. The internal signals include signals from the networked components of the interactive detector 122, including digital signals from digital signal devices, such as interactive detector 122, control server, computers, computer peripheral equipment, telephones and facsimile machines, as well as RF modulated video signals produced by RF modulation of audio/video output signals from the networked multimedia and detected data A/V equipment such as at least a television.

The network signals also include upstream signal transmission such as the RF modulated A/V signals from the network multimedia and detected data equipment which the interface devices, destination communication devices provide over CATV channel frequencies for internal use. The Downstream coax signals include both RF broadcast signals, control signals, and the home occupant RF modulated A/V signals. The broadcasting, digital signal devices, destination devices, including computers, modems, faxes and digital telephones communicate over the twisted pair. Signal splitters are used to divide the source for CATV signal among the cables thereby providing the source CATV signal with substantially constant load impedance, while also providing signal isolation between its output ports to prevent signals propagating from the source connection from being cross coupled to the other output ports. Still another object of the present invention is to provide a network capable of providing bidirectional detection signal transmission of broadband, broadcasting and interactive-infrared signals over at least a single conductor coaxial cable.

According to the embodiment of present invention, a network includes one or more single conductor coaxial cables routed within proximity to one or more local detectors forming groups of interactive network components of the interactive detector 122. Interface devices are associated with each network components of the interactive detector 122. The interface devices uses frequency division to separate the computer and media and detected data signals from the local group components in communication with the interactive detector 122 for enabling signals into broadcasting and broadband signal frequency channels within a local coaxial cable for distribution. The coaxial cable couples the signals to central control module devices such as at least a control server.

The control module or devices further receives RF broadcast television signals which it mixes with monitoring and detection signals into the broadband signal channel of each local cable. Additionally making the RF broadcast signals available to each networked components of the interactive detector 122 concurrently with the broadcasting and broadband signals from each other components of the interactive detector 122 to enable detection and communication signal effectiveness.

In the embodiment of the present invention, each interface devices includes bi-directional frequency filters for exchanging the computer and media and detected data signals from the components of the interactive detector 122 with the signals from the broadcasting and broadband signal channels of the local cable and telephone system. In a still further embodiment of the present invention, the control module devices includes a signal bus for cross coupling the broadcasting and broadband signals among the local cables and telephone utilized for enabling detection communication thereon. The bus has a signal path geometry, which minimizes signal interference within the broadcasting and broadband frequency, channels due to signal reflections occurring within the networks.

The invention further includes the use of a novel detection signal control module, which interconnects the individual coaxial cables to the CATV signal source connection without the

of detection signal splitters or detection signal combiners. The network incorporates a multi-master approach with respect to the networked components of the interactive detector 122, including the interactive detector 122 having sensory platform for detection. The network requires that the control server provides for interactive detector 122 signal speeds of at least 1.0 Mbps, a 125 Kbps signal speed for infrared control, and up to 160 television channels responsive for enabling intercommunication within the system. As shown, the network 20 includes a control module 22, which receives network signals at a plurality of network signal terminals 24-28. Each network terminal is connected to one of a plurality of electrical signal conductors 30-33 comprising the network's communication port. The communication port is the network's means for exchanging network signals between the control module 22 and the components of the interactive detector 122 at locations 38-41. The control module 22 also receives, at broadcast signal input 42, broadcast signals, such as television programming signals. The signals are either in broadband digital signals and/or analog signals, received in a radio frequency (RF) modulated signal format on line 2 from broadcast signal sources, such as CATV services, or antenna to receive broadcasts, and/or broadcast satellite services.

One novel aspect of the present network is the shared modes transmission of low frequency digital signals in the range of at least 0-5 MHz band with RF broadcast services signals above the range of at least 5 MHz through common coaxial conductors. Each individual coaxial conductor 30-33 supports bidirectional network signal transmission through simultaneous upstream network signals output from components of the interactive detector 122 to control module 22 and downstream network signals output from control module to components of the interactive detector 122. As described in the embodiment, data and information band signals (0-2.5 MHz) are transmitted at signal speeds of at least 1.0 Mbps. The command and control band signals are transmitted at signal speeds of at least 125 Kbps.

The upstream network signals are received by the control module and are separated by the control server 24 into low frequency (0-5 MHz) digital signals. The digital signals are coupled to the detection and communication means through the low pass filters 69, 70 and/or the low frequency bus 71. The high frequency (>5.0 MHz) RF signals are coupled to the detection and communication means through the high pass filters 67, 68 to the BALUMS 80, 92. The broadcast signals are combined with the media means to enable detection data signals in forming the downstream network signal. Since the low frequency and high frequency signal transmission are independent of each other, the low pass frequency filters provide a direct bypass between the control module terminals 24-28 (FIG. 1) to maintain digital signal speed.

The low frequency digital signal bands (0-5.0 MHz) and the high frequency RF signal bands (>5.0 MHz) require different interface devices between other respective type components of the interactive detector 122 and the network. The computer components in communication with the interactive detector 122 interface with the network through a network “Control server signal modulator”, such as the Control server signal modulators 102, 104 as seen in FIG. 1. The media and detected data enabled by components of the interactive detector 122 interfaces with the network through an audio/video modulator, such as the A/V modulators 106-106 b as seen in FIG. 1. Each modulator type receives the shared-mode, downstream network signals and separates the low frequency digital signals (0-5.0 MHz) from the high frequency RF signals (above 5.0 MHz), and further separates the detection data and information signal (0-2.5 MHz) from the control and command signal (2.5-5.0 MHz). The command signaling means includes at least a microprocessor 105 responsive for transmitting computer signals. Each transmitted signal enable an RF modulator to provide for RF modulation of the media and detected data signals at any of the 16 CATV and 16 UHF terminals. The terminals are responsive for enabling communication with the home occupant and reserved for channel frequencies for network distribution of signals to other components of the interactive detector 122.

Referring to FIG. 5 is a schematic block diagram of Control server signal modulator type devices 102, 104. The downstream network signal is received at a coaxial connector terminal 110 and presented jointly through lines 112 to high pass frequency filter 114 and low pass frequency filter 116. The high pass filter 114 alternately referred to as a RF modulated television video frequency filter, for filtering the downstream RF broadcast television signals and RF modulated video signals onto line 118. The low pass filter 116 segregates the low frequency digital signals onto lines 120.

The filtered RF modulated signals on the line 118 are presented through a BALUM 122, to the Control server signal modulator's video signal output 124. This carrier is amplitude modulated by the received object video signal.

With respect to the low frequency digital signals of the downstream network signals passed by filter 75 onto lines 12, low pass filter 76 couples the 0-2.5 MHz data and information frequency band signal onto line 144. The high pass filter 77 couples the 2.5-5.0 MHz command and control frequency band signal onto line 14. The impedance matching network for separating detection source provides an impedance value to signals propagating through filter 76 to the line 13. The signals approximates the characteristic impedance provided by the coaxial cable, thereby providing a substantially balanced load impedance to the unmodulated digital signals propagating in each direction such as at least bi-directionally through the filter 76.

The high pass filter 77, which is also referred to as an electrical command signal filter, is a balanced impedance, double Pi, shunt inductor—series capacitor type filter, as shown in FIG. 6.

As stated in the embodiment of the present invention, the Control server signal modulator facilitates the USB transactions by exchanging packets between the home occupant PC 45 and the network, and the network transmits the packets within its transmission of network signals to each of the other network connected Control server signal modulators. However, contrary to the USB requirement for differential output drivers, which require two conductors to send a signal, the network includes a television and uses a single conductor coaxial cable to distribute the detection signal to enable network signals. The network's communication port coax, however, is much longer than 5 meters since it distributes the network signal throughout the house. The processor in turn relays the downstream transaction signal to the PC 45. Conversely, the upstream serial IrLAP digital signals on line 14 from the FET 154 are back-flowed through the low pass frequency filters 75, 77 to the coax connector 110.

As stated in the embodiment containing the network of the present invention, the signal transmission format of the data and information band signals is a serial digital bit signal transmitted in serial digital form, without signal modulation. These non-modulate signals are transmitted through the coaxial conductors in a shared mode with the RF broadcast services signals distributed by ADT, America Security Inc. or the like. In the disclosed network embodiment the signal bit speed is substantially equal to 1.0 Mbps. In the best mode embodiment the low pass filters within the signal transmission path, including the filters 69, 75 and 76 provide sufficient dampening of the digital signal ringing to accommodate higher bit speeds within the 0 to 2.5 MHz band.

The network's 2.5-5.0 MHz command and control band is used to facilitate wireless infrared (IR) signal communications associated with the interactive detector 122 enabling component of the network. Referring again to FIG. 1, the network's wireless IR communications function includes the operator/home occupant's control of said network through a control module connected to components of the interactive detector 122. This is also enabled through an IR remote control device 65, or the home occupant's IR wireless means responsive for enabling transfer of data and/or signal commands between at least an external device such as a lap top computer and network connected PC 45. This is enabled by detecting IR signals emitted in any location serviced by the network and converting the detected IR signal to a modulated signal which is routed to all network locations, and demodulating the distributed signal back to IR for detection by the intelligent components of the interactive detector 122.

The emitted IR signals within a network site, either consumer IR or IrDA protocol, are detected by IR detectors disposed within television, the walls or ceiling of the home, and the Control server signal modulators 102, 104 as seen in FIGS. 1, 4, and/or A/V modulators 106-106 b as seen in FIG. 1. Similarly, network emitter responsive for enabling interactive communication with the network IR detectors 192, 194 provides forward field-of-view coverage. The IR/IrDA bridge device 164, exchanges detection data between the IR emitter-detector-123 and the microprocessor 105,56 The modulator/demodulator or frequency modulates the converted signal content at a selected modulation frequency within the 2.5 to 5.0 Mhz command and control frequency band. The modulated IR signal is back-flowed through the filter 146 as well as the low pass filter 116 to the coax connector 110, and transferred in shared mode with the RF broadcast service signals through the communication port 134 as seen in FIG. 1, enabling the control module 22. Of the other modulators connected to the network to stay in communication. The IR emitter broadcasts the signal to devices carried by home occupants and/or security agencies. With a USB PC connected to the network through a Control server signal modulator, the PC video output can be displayed on, and functionally controlled from, any TV in the house. This occurs through home occupant input by through the control module 20 to the network remotely controlled devices as seen in FIG. 1. The remotely controlled devices are a combination of wired/wireless infrared (IR) and wired/wireless RF unit, which allows for direct communication between home occupant and the network, connected PC, enabling on-screen-home occupant-friendly interface technology.

Home occupant actuation of the menu button causes the remote control to substantially simultaneously emit a 916 MHz RF command signal and an IR code signal. In the Control server signal modulator the RF command signal is forwarded from receiver 19 to microprocessor 105 134 and, through USB connector 14, to the home occupant's PC 45. The home occupant PC functions as the wireless server for the network, allowing control server 24 to function as the main centralized communication and control device having USB and cable ports. At the same time allowing the network modulator at the home occupant location to enable detection of the remote control IR code signal and notifies the host PC of the home occupant location over the control and command band (2.5-5.0 MHz). The PC is responsive for changing the TV channel at the home occupant location to a PC Menu channel selected from among the reserved RF spectrum channels for outputting detection data. 

1. VIEW A PSI apparatus for detecting fault and for monitoring contextual characteristics influential to pressure change within a closed system of at least a vehicle component, wherein said apparatus comprising at least a sensor embedded in at least a silicon substrate and etched in at least a micro-fibered material to enable at least a platform for detection, and wherein said micro-fibered material comprises at least a first material having excellent electrical properties and wherein said first material is fused/embedded in at least a second material for manufacturing at least an element of said closed system of said vehicle component, wherein said second material forming an element of at least a vehicle wheel, said wheel comprising one of said closed system, and said first material containing plurality sensors to enable at least an effective sensory platform having means for enabling detection of context base characteristics affecting pressure change within said closed system, and wherein said sensory platform further including means for enabling interactive monitoring and communication of sensed object in connection to said contextual activities and movements within said closed system responsive for enabling detection and wireless communication thereon, comprising: at least a sensor means; at least a detection means; at least a reader means; at least a processing means; a plurality of operational sensors functionally embedded in at least an RFID chip forming said apparatus, wherein each said sensors having a predefined nominal operating state and each said sensor generating respective electrical signals in response to each said nominal operating state of said closed system; a database means for storing samples of responses in reference to said electrical signals for communication thereon; a control means in communication with said processing means responsive for enabling said database activation in response to detected characteristics collected by said monitoring and detection means within said closed system indicative of enabling communication to the operator of said vehicle and comparing said detected data with the data in said database means; means for receiving signals and for outputting modulated signals from at least a processing means; an analyzer means responsive to said electrical signal in response to said detected/collected data for performing data analysis and for analyzing said predefined detection parameters indicative of at least a potential variance of said modulated signal in relation to said operational component's continuous operating state; a computer means located remotely within said vehicle and from said closed apparatus, wherein said computer in communication with said control means enables classifying said modulated signal in at least said continuous operating state and at least an irregular operating state in response to said operational component of the vehicle; a transmitting means in communication with at least said sensory platform for automatically transmitting at least said detected data and enabling comparing said data with said stored samples responsive for effective detection and communication; means for amplifying said communication signals to said computer means responsive for outputting at least a generated matching coded signal, wherein said generated signal is sent to said receiving means for enabling broadcasting voice auditory communication to an operator of said vehicle; speaker means for outputting said communication thereon; Antenna means in communication with said receiving means and said transmitting means for outputting said coded signals through radio wave transmission in response to enabling communication between at least said transmitting means and at least said receiving means through frequency signals such as at least a radio wave indicative of interactively transmitting communication within at least said closed system to the operator of the vehicle; at least a sensor means operating within at least a defined principles of detection to enable detection of said classified contextual characteristics in at least said closed system forming a component of said vehicle, wherein said computer means receives said transmitted data samples and said classified contextual characteristics enables data classification in accordance with said predefined nominal and/or irregular operating states; means for interactively enabling wireless communication between said detection platform and said computer means to enable safety and security of said vehicle through continuous monitoring of said vehicle component; and means for enabling interactive monitoring of pressure change within a closed system, wherein said means further includes at least a detection platform with sensors embedded in a silicon substrate and etched inside at least a micro-fibered material responsive for enabling effective detection means and for generating coded signal of at least a sensed agent influential to pressure change within said closed system, wherein said platform further include means for transforming said detection signal into electrical energy to enable interactive communication thereon.
 2. VIEW A PSI apparatus for detecting fault of claim 1, wherein said transmitter means in communication with said detection platform transmit at least stored samples collected over a predetermined interval to at least a receiving means responsive for enabling interactive processing and communication, wherein said interactive processing and communication means includes at least a microprocessor control means connected to at least a memory, and wherein said interactive processing and communication means interfaces with at least an antenna means for providing signal communication there-between and for filtering out said signal output to enable improved signal to noise ratio and to enable said communication clarity.
 3. VIEW A PSI apparatus for detecting fault of claim 2, wherein said transmitted samples comprises a predetermined contextual characteristics influential to change in tire pressure responsive to said closed apparatus for generating electrical signal in response to communication signal from said detection platform, and wherein said communication signal is transmitted through waves such as at least radio wave frequency, wherein said electrical signal is comparably matched with a pattern of detection generated by at least said coded samples and empowers by said frequency energy there-between.
 4. VIEW A PSI apparatus for detecting fault of claim 3, wherein said sensing means includes at least a MEMS sensor embedded in a silicon substrate and further includes plurality sensors all etched/fused in said micro-fibered material having excellent electrical properties for enabling excellent thermo-sensory platform for detection and for generating data indicative of said detection of at least a contextual characteristics in comparison with said transmitted samples collected prior to said detection, wherein said detection corresponding to a first predetermined object responsive to said electrical signal, and wherein said transmitted samples collected after said detection corresponding to a second predetermined object responsive to said electrical signal, wherein said electrical signals responsive for enabling communication indicative of shared detection characteristics common to influencing pressure change within an operational component of a closed system of a vehicle, and wherein said operational closed system includes an assembled vehicle tire in rotation and enabling interactive communication from a sensory platform through at least a receiving means to at least a control means.
 5. VIEW A PSI apparatus for detecting fault of claim 4, wherein said first and second predetermined object enabling said electrical signal are determined in response to said communication from said detection platform with said receiving means, wherein said receiving means further includes sensors, and said receiving means embedded in the body of at least a valve stem for enabling interactive communication with said control means through at least a code-able RFID chip indicative of communicating the same to at least a vehicular network for establishing driving safety and security thereon.
 6. VIEW A PSI apparatus for detecting fault of claim 1, wherein said transmitted samples comprises at least a predetermined object for enabling detection responsive for generating said electrical signals in connection with said sensing and detection means, wherein said means enables interactive communication and interfaces with plurality devices to enable communication to said network, and wherein said plurality devices further includes at least an RFID chip embedded in the body of at least a valve stem and having at least an antenna in communication with said control means responsive for initiating at least a shared data environment in connection with at least a vehicular monitoring means and communication center.
 7. VIEW A PSI apparatus for detecting fault of claim 1, wherein said receiving means and said sensing means further includes at least an RFID code-able chip having at least an antenna made of at least a non-ferrous material for enabling communication indicative of at least a detection of said predetermined object, and wherein said code-able sensing means includes means for enabling detection of sudden change in wave frequency inside said closed system indicative of said contained characteristics influential to pressure change in response to said electrical signal, and wherein said electrical characteristic is at least one of resonant frequency, harmonic spectra, and at least a Q factor, wherein said electrical signal and said wave frequency further enable interactive communication through at least a wireless networking means to at least an operator of said vehicle.
 8. VIEW A PSI apparatus for detecting fault of claim 6, wherein said predetermined object comprises plurality objects in response to said controlled electrical signals received from said computer means, and wherein said predetermined means further includes at least a transducer for transforming said fault signals into said electrical energy and enabling interactive communication there-between, wherein said means for enabling interactive communication includes at least a means for empowering said sensory platform to enable recognition of at least a detected/received signal responsive for enable electronic simulation of responses indicative of communicating at least a detection of said contextual characteristics to the operator of the vehicle.
 9. VIEW A PSI apparatus for detecting fault of claim 1, wherein said analyzer compares said stored samples to at least a predetermined pattern of recognition in relation to said electrical signal and generating responses indicative of said comparison to enable communication, wherein said communication signal indicative of responding to said detected data to enable generating effective detection and communication environment in connection to at least a control means, and wherein said control means enables interactive wireless communication there-between indicative of responding to at least a sensed contextual characteristics influential to pressure change within a closed system.
 10. VIEW A PSI of a tire air pressure measuring system for measuring the pressure of a closed system as claimed in 1, further comprising: a sensory platform fused/etched to the tire of a wheel assembly and extending inwardly from the rim of the wheel assembly toward at least a tire assembly such that the sensory platform detects and reports all contextual characteristics contained in the wheel assembly; at least one sensor fused/etched to the sensory platform and away from the rim of the wheel assembly such that at least one sensor does not protrude from the wheel assembly; a communication means in communication with the at least sensor and the RFID chip at the valve stem of the wheel assembly; and wherein the at least one sensor provides an indication of air pressure or contextual characteristics of the closed system to an operator.
 11. The view a PSI system according to claim 10, wherein the sensory platform further includes a strip of plurality sensors attached to the inner surface of the wheel assembly and/or fused/etched to the tire of the wheel assembly by using adhesive means.
 12. The view a PSI system according to claim 11, wherein the plurality sensors comprises at least one of micro-sensor elements, MEMS, infrared, RFID chip, and wherein at least one sensor communicates a audio/visual indication of the air pressure drop or contextual characteristics of the closed system.
 13. The view a PSI system according to claim 1, wherein said plurality sensor includes at least one said sensor that communicates audio/visual indication of at least air pressure drop or contextual characteristics influential to pressure change of a closed system, and wherein said plurality sensor includes a pair of acoustic wave sensor.
 14. A vehicle tire pressure monitoring apparatus for detecting contextual characteristics influential to pressure change within a closed system, comprising means for detecting fault, wherein said means includes sensors embedded in at least a silicon substrate, and wherein said silicon substrate is etched in at least a micro-fibered material having excellent electrical properties to enable at least an excellent platform for detection, wherein said micro-fibered material is further wired in a second material to form at least a component of said closed system having said detection platform responsive for analyzing a predefined parameters for detection indicative of at least a variance of operational state of at least a wheel of said vehicle components forming at least one of said closed system, and wherein said platform and said predefined parameters forming a pattern of detection common to generating at least a comparison to a stored sample in connection to said vehicle component, at least one said component further includes a tire having a rotation means designed to improve the effectiveness of detecting at least a fault to enable interactive wireless communication thereon, comprising a transmitting means activated by at least a sensory platform to automatically transmit at least a detected data to at least an analyzer/reader for comparing with stored samples and enable at least a computer means to output a generated matching coded signal, wherein said generated signal is transmitted to at least receiving means responsive for enabling communication thereon; receiving means in communication with at least said transmitting means; means for verifying detected signal communication to enable interactive wireless communication to at least a control means; RFID chip means having at list a transmitting and a receiving means responsive for enabling communication with said vehicle operator; Control means in wireless communication with at least said receiving means indicative of allowing signal communication through at least said transmitting means to a detection platform, wherein said control means enables communication between said RFID chip secured in at least a valve stem and said transmitting means to enable sensory interaction indicative of revealing at least a detection of contextual characteristics influential to tire pressure change; means for transforming said detection signals into at least an energy form; means for utilizing said energy form to enable at least an interactive wireless communication to at least said vehicle operator; means for enabling communication with at least a processor means responsive for providing detection status to enable interactive wireless communication thereon; means for converting sounds within said closed system into an electrical signal; means for enabling said electrical signal to be sampled for generating samples of said detected signal; means for detecting at least a fault associated with at least a rotational component of a vehicle; means for enabling audio vocal/audio visual communication in response to a sensed signal indicative of at least a detection of contextual characteristics responsive to said fault detection; and processing means for coordinating transient signals and for receiving sensed signal communication in response to detection output.
 15. A vehicle tire pressure monitoring and fault detection apparatus of claim 14, wherein a receiving means in connection with at least an analyzer enables performance of a predetermined analysis of detection data in response to a sensed contextual characteristics, and wherein a sensing means for initiating said communication includes at least a platform for enabling said detection, wherein said analyzed detection characteristics are transformed into electrical energy responsive for initiating communication to the vehicle operator.
 16. A vehicle tire pressure monitoring and fault detection apparatus of claim 15, wherein said transmitter comprises of at least a transceiver and wherein said predetermined analysis is controlled by at least a software in connection with at least a computer means connected to said transceiver and said sensing means, wherein said sensing means includes at least a detection platform forming means for transforming at least a sound energy into useful analytical signal responsive for generating data to at least a control means responsible for enabling interactive wireless communication there-between indicative of at least said sensed characteristics influential to at least a tire pressure change.
 17. A vehicle tire pressure monitoring and fault detection apparatus of claim 16, wherein said software having means for verifying communication signals from at least a sensing means, and wherein said sensing means in communication with at least a computer means responsive for analyzing the detection severity affecting the operational state of the closed system of a vehicle component, and fault detection apparatus further includes means for transforming at least the energy generated from at least a sound wave within the closed system into useful analytical signal responsive for generating data indicative of updating the vehicle operator of the fault severity affecting the safety operation of the vehicle component, wherein at least a control means enables interactive wireless communication there-between indicative of at least a sensed contextual characteristics within at least a defined environment of said vehicle component.
 18. A vehicle tire pressure monitoring and fault detection apparatus of claim 17, wherein the sensing means further includes at least a sensor embedded/fused in an RFID chip and etched in at least a tire material forming at least a sensor circuitry, wherein said sensor circuitry further comprising a transmitter means embedded in said plurality sensors forming a detection platform having at least a monitoring means, wherein said monitoring means in signal communication with said detection means for enabling detection of characteristics affecting tire pressure change and for transmitting said signal communication into electrical energy, and wherein said sensory circuitry further includes means for analyzing said communication signal indicative of detecting at least an object, and wherein said sensing means for detecting said object having means for detecting at least contents within sound wave and further comprises means for transforming said sound wave signal into electrical energy responsive for enabling random monitoring of characteristics affecting at least a vehicle wheel in rotation.
 19. A vehicle tire pressure monitoring and fault detection apparatus of claim 18, wherein said means for transforming said sound wave into electrical energy includes at least a transducer in connection with said sensing means for transforming the effects of at least a variation of air molecule in interaction with at least the molecular activities of at least a tire surface forming said closed system into electrical energy responsive for enabling interactive communication, wherein said means for transforming said sound wave further enables at least a transformation of interactive activities into useful signal communication through at least a sensory platform having a sensory circuitry in connection with at least control means, and wherein said sensor circuitry comprises at least a sensor means embedded in at least a silicon substrate, wherein said embedded sensor means and said silicon substrate are etched in at least a re-enforced micro-fibered material forming said detection platform.
 20. View a PSI for monitoring contextual characteristics of a closed system such as a tire system used in a motor vehicle having plurality of tires as claimed in 15, further comprising: a plurality of sensory platform, each being in signal communication with at least a sensor installed in a valve stem, such as, as an example, an RFID chip, and having a wireless signal transmitting means for transmitting communication signals there between, at least one said communication signal comprising a specific code transmission indicative of at least a condition of the tire, such that said condition is a member of the context base characteristics influential to tire pressure change; plurality of antenna modules connected and in communication with each said sensor in the said platform for transmitting/receiving signal communication; and a transmitting/receiving means, electronically coupled to the antenna modules, for transmitting and receiving signals; an electronic switch means selectively coupled to the antenna modules; at least a radio frequency receiver coupled to the electronic switch means for enabling a database signal representation of the said context base characteristics influential to tire pressure change; and a central processing unit “CPU” coupled to at least a reader having radio frequency transmitting and receiver means, for controlling detection/safety communication to the operator of the vehicle.
 21. View a PSI for monitoring contextual characteristics of a closed system such as a tire system used in a motor vehicle having plurality of tires as claimed in 20, wherein said signal is a radio frequency “RF” signal and wherein said closed system further includes a tire and said contextual characteristics of the tire consisting of, as an example, rim corrosion, tire unbalanced, tire vibration, tire pressure change, temperature change, tire acceleration, and at least a Q factor, etc.
 22. View a PSI for monitoring contextual characteristics of a closed system such as a tire system used in a motor vehicle having plurality of tires as claimed in claim 21, wherein said transmitting and receiving means further comprises a sensory platform and/or a valve stem RFID chip in communication with said central processing unit.
 23. A vehicle tire pressure monitoring and fault detection apparatus of claim 11, wherein said means for transforming said detection into RF signal enables audio/visual communication to said vehicle operator indicative of communicating detection of contextual characteristics influential to at least a tire pressure change within said closed system's environment, and wherein said environment having means for analyzing signal communication from at least a sensor means, wherein said means for analyzing said signal communication comprises at least an antenna means, a receiving means, and a transmitting means coupled to the said sensor means having at least an RFID chip, and wherein at least one said sensor means includes means for energizing at least a detection platform for enabling analyzed data transmission through interactive wireless communication with at least a wireless control means, further comprising; Means for receiving radio frequency signal from at least a sensor; Means for transmitting radio frequency signal to at least an environment; RFID chip for interactively receiving/transmitting output signals from said sensor means to a location external to said closed system's environment; Means for filtering out said signal output; Means for storing coded data indicative of said sensed signal and said detection signal indicative of predetermined detection signal input/output; Means for upgrading energy level of said detection platform for enabling at least communication clarity; sensor circuitry means comprising a detection platform having at least a monitoring means responsive for communicating detection characteristics affecting environmental conditions and the safety of vehicle operator/occupant; means for enabling interactive wireless communication and for analyzing sensed communication signals from at least a sensor to enable a network of communication thereof; and wireless control means for controlling contextual signal transmission and signal receivable in response to detection characteristics:
 24. A vehicle tire pressure monitoring and fault detection apparatus of claim 23, wherein said means for energizing said detection platform includes at least a transmitter in communication with said sensing means, said sensing means having means for measuring at least a change in electrical properties caused by the interaction of at least a foreign object on said sound wave responsive for empowering said means to enable effective detection of contextual characteristics influential to pressure change within at least a closed system, wherein at least a receiving means on a valve stem within said closed system receives said detection signal and enable communication with at least a control means for enabling at least an audio/visual communication with a vehicle operator.
 25. A vehicle tire pressure monitoring and fault detection apparatus of claim 24, wherein said receiving means on said valve stem includes at least an RFID chip having at least an antenna and secured within the said valve stem seat for receiving output signal from at least said detection platform in connection with said sensing means circuitry, and wherein said RFID chip communicates said output signal to at least a control means, wherein said control means includes at least CPU responsive for transforming at least a mass change within said closed system and at a modified surface caused by at least a mass absorption of at least an object influential to pressure change, into properties of a support material responsive for enabling analyzing signal communication from said sensor means through at least an antenna means coupled to the sensor means, wherein said sensor means includes at least a transmitter for energizing the detection platform and enables interactive wireless communication to at least a wireless control means.
 26. A vehicle tire pressure monitoring and fault detection apparatus of claim 25, wherein said sensing means is connected to at least a control means having at least a microprocessor and includes a data storage means in connection with at least a transmitting/receiving means, means for filtering out signal output responsive for enabling communication clarity, and wherein at least one said means empowers the detection platform to enable transforming detection signals into at least an electrical energy indicative of at least a sensed object within at least a defined vicinity common to at least a tire in rotation.
 27. View a PSI apparatus having a detection means for detecting contextual characteristics influential to pressure change within a closed system as claimed in 14, wherein said detection means includes at least a detection platform having sensors embedded in at least a micro-fibered material having excellent electrical properties for enabling detection efficiency, and wherein said micro-fibered material is etched in at least a silicon substrate to further enable efficient signal conduction, wherein the silicon substrate is etched and/or fused on a second material having characteristics for designing said detection platform, and wherein said closed system forming the basis for detecting inflated pressure change and all characteristics affecting said change for enabling communication thereon, further comprising: a first set of interactive detectors in at least a platform circuitry, each of the interactive detectors being selected to detect at least a pressure change, temperature conditions, contamination, and other characteristics influential to pressure change, and a second set of interactive detectors being selected to detect at least foreign sounds, unparalleled motion of the said closed system; at least a sensor for detecting the contextual object type within the closed system, each said sensors having at least a transmitting and receiving means responsive for enabling at least a wireless detection network and signal communication with the first set and the second set of interactive detectors; at least a reader for reading said communication signal, wherein said reader having at least a response means for signaling the operator of said vehicle the detection of at least one of the first set and the second set of interactive detectors, said interactive detectors responsive for initiating the actuation of at least a thermostat for controlling the temperature condition within the closed system; at least one transmitting means for transmitting signals from at least one of the first set and the second set of interactive detectors; at least one receiving means for receiving the signals from the said transmitting means; a control means having at least a microprocessor in communication with said detection means for receiving the signals, storing and processing data from the receiving means, and for enabling audio visual communication with the operator of said vehicle having said closed system; and a broadcasting means in communication with a speaker means for outputting said audio visual responses from said microprocessor to at least the operator of the vehicle in human voice auditory indicative of the first set and the second set of interactive detection selectively reporting sensed activities contained in the closed system for eliminating the presence of an emergency and for initiating safety and the safe operating state of the said vehicle.
 28. View a PSI apparatus of claim 27, wherein at least one of the sensors is a temperature sensor, each said sensor wired in a detection platform, and said platform located in a selected pressure point of said closed system for tracking contextual characteristics influential to pressure change within the said closed system responsive for continuously signaling the operator of the said vehicle the safety conditions of said closed system in the presence of at least an emergency situation, wherein at least one response means located in selected areas of said vehicle responsive for enabling said broadcasting in human voice auditory the specific presence of the emergency.
 29. View a PSI apparatus of claim 28, wherein the second set of interactive detectors includes at least an RIFD chip located within at least a valve stem of said closed system responsive for outputting communication signals from the detection platform to at least a control means in the presence of at least a detection of contextual characteristics influential to pressure change, and wherein at least the control means selectively communicates said sensed activities to at least a microprocessor to enable remote communication to the driver of said vehicle, the specifics of said platform detection.
 30. View a PSI apparatus of claim 29, wherein at least a wireless communication is interactively transmitted through at least one of: radio waves, microwaves, and ultrasonic waves, wherein said wireless communication means includes means for upgrading the energy level of said detection platform through at least an energy empowering means, and wherein said energy empowering means includes means for recharging said level to empower at least a transmitter, a receiver, and at least a detection platform.
 31. View a PSI apparatus of claim 30, wherein said signals from the first set and the second set of interactive detectors are transformed to readable data relating to each unique specific detection influential to pressure change within a closed system, and wherein said data is stored, and each stored data is communicated to at least the operator of the vehicle having said closed system.
 32. View a PSI apparatus of claim 31, wherein said means for transforming said data have means for transforming at least a detected signal into useful analytical energy for generating data to at least a control means, said control means responsive for enabling interactive wireless communication there-between indicative of reporting at least a sensed contextual characteristics within at least a defined vicinity common to said closed system, and wherein said means for transforming said data transmit said analytical energy to locations external to said closed system.
 33. View a PSI apparatus of claim 27, wherein the signals are modulated prior to transmission, and said signal further include a human voice auditory messaging responsive to the specific nature of the detection, wherein the first set of interactive detector includes at least one of: temperature detector, wheel unbalanced detector, and contextual object detector.
 34. View a PSI apparatus of claim 33, wherein at least an antenna is embedded in the detectors for transmitting detected signals to at least a remote location, and wherein the said antenna is one of at least a redundant antenna and at least a diverse antenna for reducing the likelihood of false signal communication.
 35. View a PSI apparatus of claim 34, wherein said interactive detectors enable communication signal for transmission to at least an RFID chip located at least at a valve stem of said closed system, wherein said RFID chip having at least readable means and being in constant communication with at least a control means responsive for interactively enabling activation of a microprocessor to enable at least an audio/visual voice auditory communication with the operator of said vehicle.
 36. View a PSI apparatus of claim 35, wherein transistors are incorporated into the detection platform for simplifying signal output for the interactive detectors, said transistors setting a desired frequency range suitable for transmission of detection signals through any one of: radio waves, microwaves, and ultrasonic waves, and wherein said transistors further include means for enabling thermal control of said platform and low operational voltage of said control means.
 37. View a PSI apparatus having a detection means for detecting contextual characteristics influential to pressure change within a closed system as claimed in 36, wherein said detection means includes at least transistorized switches embedded in said detection platform responsive for elevating the electrical characteristic level of said first/second material, and wherein said electrical characteristics further includes at least one of resonant frequency, harmonic spectra, and at least a Q factor.
 38. View a PSI apparatus having a detection means for detecting contextual characteristics influential to pressure change within a closed system, wherein said detection means includes at least a detection platform having sensors embedded in at least a micro-fibered material having excellent electrical properties for enabling detection efficiency, and wherein said micro-fibered material is etched in at least a silicon substrate responsive for enabling efficient signal conduction, wherein the silicon substrate is either etched or fused on a second material forming said detection platform on at least a component of the closed system, and wherein said closed system forming the basis for detecting inflated pressure change and enabling communication thereon, comprising: first plurality of interactive detectors in at least a detection platform, wherein each of the plurality of interactive detectors being selected to detect at least one of characteristics influential to pressure change, wherein one such interactive detector include at least a temperature detector, a contextual object detector, and at least a wheel vibration detector, and wherein at least a second plurality of interactive detectors being selected to detect at least one of selected sounds, unparallel motion, and pressure change; a plurality of transistorized switches embedded on at least a detection platform for enabling thermal adjustment to environmental condition influential to said closed system operation, said transistorized switches being in connection with at least plurality temperature sensors, each said temperature sensor having at least a transmitting and receiving means, said transmitting and receiving means enables networking and wireless communication with the first and the second plurality of interactive detectors and the operator of said vehicle, and wherein each temperature sensor further monitors the presence of thermal change of the said closed system, and each transistorized switches further enabling adjustment to said thermal change affecting the said closed system, and wherein said adjustment includes manufacturers recommended operating temperature and PSI range; a plurality of audio speakers, each audio speaker connected to at least a control means, wherein said control means receives communication signal from at least the first plurality sensors, the second plurality sensors, and wherein said communication signal is readable by at least a microprocessor, said microprocessor being in wireless communication with the first and second plurality of interactive detectors responsive for enabling a selected human voice response indicative of at least a selected specific detection; a plurality of transmitting means, each transmitting means responsive for transmitting signals from one of first and second plurality of interactive detectors; at least one receiving means for receiving signals from at least one of the first and second plurality of transmitting means; at least one microprocessor for receiving, storing, and processing data from at least the receiving means, and for communicating said data through at least one of the plurality speakers to the operator of the vehicle; at least one of said receiving means being an RFID chip embedded in at least a valve stem of an inflatable closed system; at least one of said transmitting means being an RFID chip embedded in at least a valve stem of an inflatable closed system; at least said RFID chip receiving wireless communication signals from the said plurality detectors and communicating said received signals wirelessly to at least said microprocessor, wherein the said microprocessor responsive for enabling audio visual communication to at least the operator of a vehicle through at least one of the said plurality speakers; at least one speaker means for outputting said human voice auditory message from at least a processor means and for selectively broadcasting sensed emergency conditions to at least the operator of the said vehicle to enable direct voice over safety “DVOS” for accident prevention.
 39. View a PSI apparatus of claim 38, wherein the wireless communication is transmitted through at least a one of radio waves, microwaves, and ultrasonic waves, and wherein the second set of interactive detectors includes at least an RFID chip embedded inside at least a valve stem for enabling communication from the detection platform to at least the microprocessor.
 40. View a PSI apparatus of claim 39, wherein the signals from the detection platform are unique to each detector, and wherein the microprocessor stores the unique detected data relating to each unique characteristics influential to pressure change.
 41. View a PSI apparatus of claim 40, wherein the detection platform includes at least a first set of interactive detectors, at least a second set of interactive detectors, and at least a control means, and wherein said first set of detectors, said second set of detectors, and said control means communicate wirelessly through a wireless network to the operator of the vehicle.
 42. View a PSI apparatus of claim 41, wherein the first set of interactive detectors and at least the second set of interactive detectors having an antenna, and wherein each antenna is one of a redundant antenna and a at least a diverse antenna, wherein said antennas enable signal transmission to at least a remote control means.
 43. View a PSI apparatus of claim 42, wherein said detection signals are encoded, and wherein encoded signals are modulated prior to transmission, wherein said modulated signals further includes a human voice auditory message responsive to the specific detection of the contextual characteristics within the closed system, and wherein at least the nature of each signal is communicated to the operator of the vehicle to eliminate the presence of at least an emergency.
 44. A method of view a PSI for monitoring contextual characteristics and for measuring the pressure of closed systems using a sensory platform, comprising the steps of: embedding at least a sensor in a silicon substrate; etching the silicon substrate in a micro-fibered material to form a sensory platform; mounting the sensory platform on at least a tire of a wheel assembly and extending the said platform inwardly from the rim of the wheel assembly toward at least a tire, such that the sensory platform detects and reports all the contextual characteristics contained in the wheel assembly; mounting at least one sensor on the sensory platform of a valve stem and away from the rim of the wheel assembly such that at least one sensor does not protrude from the wheel assembly, for enabling communication between the tire sensory platform and the operator of a vehicle; communicating said detection data communication between said tire sensory platform and the operator of a vehicle in at least a human voice auditory message/signal; and providing said voice auditory message in response to broadcasting the specific indication of contextual characteristics detected within the closed system, such as at least temperature change, pressure change, or rim corrosion.
 45. A method of view a PSI for monitoring contextual characteristics and for measuring the air pressure as claimed in 44, wherein the sensory platform further includes a code-able method for a tire monitoring device, comprising the steps of: embedding plurality sensors in the silicon substrate and etching the silicon substrate in a micro-fibered material forming a sensory platform for use in plurality of tires in a motor vehicle, each sensory platform having a wireless signal transmitter for transmitting a signal to at least a second sensor such as an RFID chip mounted in the valve stem, said signal including a specific code representation of a context base tire condition and said RFID chip communicating said specific code to at least a reader located inside the vehicle; providing a plurality of antenna modules in each said platform for transmitting/receiving signal communication; Connecting a memory between at least a sensor and an antenna for defining the coded signals; confirming the intensity of detection characteristics through wireless communication with at least the tire sensory platform, the valve stem sensor, the reader, and the operator of the vehicle.
 46. A method of view a PSI for monitoring contextual characteristics and for measuring the air pressure as claimed in 45 wherein the memory provides means for identifying the specific transmitted codes, and wherein said step of embedding plurality of sensor in the silicon substrate and etching the silicon substrate in a micro-fibered material for use in plurality of tires in a motor vehicle further comprising the steps of: confirming the specific code of the sensory platform and communicating said code through at least an antenna module from which the signal is being transmitted to at least an RFID chip if the intensity of the detection is higher than a predetermined value.
 47. A method of view a PSI for monitoring contextual characteristics and for measuring the air pressure as claimed in 46, wherein said signal from the said sensory platform to the valve stem RFID chip, and from the RFID chip to the reader is a radio frequency (RF) signal, and said signal to the operator of a vehicle is a voice auditory message/signal.
 48. A method of view a PSI for monitoring contextual characteristics and for measuring the air pressure as claimed in 47, wherein said closed system further includes a tire and said contextual characteristics of the tire consisting of, as an example, rim corrosion, tire unbalanced, tire vibration, tire pressure change, temperature change, tire acceleration, and at least a Q factor, etc.
 49. A method of view a PSI for monitoring contextual characteristics and for measuring the air pressure as claimed in 48, wherein said sensory platform further includes a code-able method for the said tire monitoring system, and comprising the steps of: providing plurality of sensory platform fused to plurality of tires in a motor vehicle, each sensory platform having a wireless signal transmitting means for transmitting communication signal specific to said code representation of a tire condition. providing a plurality of antenna modules in each said platform for transmitting/receiving signal communication; selectively coupling the antenna modules with at least a sensor in the said platform; dividing the RF signal into at least a database signal for communicating with at least a reader; determining a tire acceleration value and comparing said value per tire of the said vehicle with a pre-set tire acceleration value per vehicle speed; determining the sensory platform operational state functions based on the intensity of the RF amplitude signal; and determining were the sensory platform that transmits the signal is installed, such as on the left or on the right of the motor vehicle, based on the coded information value and/or the destination of the communication signal between the valve stem and the reader, thereby identifying the specific installation position of the RFID chip and/or the specific code of the sensory platform that transmits the signal.
 50. A method of view a PSI for monitoring contextual characteristics and for measuring the air pressure as claimed in 49, further comprising the steps of: connecting a memory between at least a sensor and an antenna for defining the coded signals; and confirming the intensity of detection characteristics through wireless communication with at least the tire sensory platform, the valve stems sensor, the reader, and the driver of the vehicle.
 51. A method of view a PSI for monitoring contextual characteristics and for measuring the air pressure as claimed in 50, wherein said closed system further includes a tire and said contextual characteristics of the tire consisting of, as an example, rim corrosion, tire unbalanced, tire vibration, tire pressure change, temperature change, tire acceleration, at least a Q factor, etc. 52 View a PSI apparatus having a detection means for detecting contextual characteristics influential to pressure change within a closed system as claimed in 38, wherein said detection means includes at least a detection platform having sensors embedded in at least a micro-fibered material having excellent electrical properties for enabling detection efficiency, and wherein said micro-fibered material is etched in at least a silicon substrate to further enable efficient signal conduction, wherein the silicon substrate is either etched or fused on a second material for designing said detection platform on at least a component of the closed system, and wherein said closed system forming the basis for detecting inflated pressure change and enabling communication thereon, and having means for analyzing signal communication from at least a sensor means, said sensor means coupled to at least an antenna means and further includes at least a transmitter for energizing said detection platform and for enabling analyzed data transmission through interactive wireless communication with at least a wireless control means, further comprising: at least a sensing means embedded in a silicon substrate and etched into at least a micro-fibered material; means for attaching said micro-fibered material into at least second material forming the closed system for enabling a sensory platform; means for receiving said signal and for analyzing said signal in relation to a wave pattern representation of at least said contextual characteristics; means for converting said analyzed signal into a digital communication signal thereon; detection platform having first plurality of interactive detectors, wherein each of the plurality of interactive detectors being selected to detect at least one of characteristics influential to pressure change, such that at least a temperature detector, a contextual object detector, and at least a wheel vibration detector are interactively incorporated, and wherein at least a second plurality of interactive detectors being selected to detect at least one of selected sounds, unparallel motion, and pressure change; a plurality of transistorized switches embedded on at least said detection platform for enabling thermal adjustment to environmental condition influential to said closed system operational state, said transistorized switches being in connection with at least plurality temperature sensors, each said temperature sensor having at least a transmitting and receiving means, said transmitting and receiving means enables networking and wireless communication with the first and the second plurality of interactive detectors, and wherein each temperature sensor further monitors the presence of thermal change of the said closed system, and each transistorized switches further enabling adjustment of said thermal change of the said closed system to at least a manufacturer recommended operating temperature and PSI range; a plurality of audio speakers, each audio speaker connected to at least a control means, wherein said control means receives communication signal from at least the first plurality sensors, the second plurality sensors, and wherein said communication signal is readable by at least a microprocessor, said microprocessor being in wireless communication with the first and second plurality of interactive detectors responsive for enabling a selected human voice output indicative of at least a selected specific detection; a plurality of transmitting means, each transmitting responsive for transmitting signals from one of first and second plurality of interactive detectors; at least one receiving means for receiving signals from at least one of the first and second plurality of transmitting means; at least one microprocessor for receiving, storing, and processing data from at least the receiving means, and for communicating said data through at least one of the plurality speakers to the operator of a vehicle having said closed system; at least one of said receiving means being an RFID chip embedded in at least a valve stem of an inflatable closed system; at least one of said transmitting means being an RFID chip embedded in at least a valve stem of an inflatable closed system; at least one said closed system being a complete tire assembly; at least said RFID chip receiving wireless communication signals from the said plurality detectors and communicating said received signals wirelessly to at least a microprocessor, wherein the said microprocessor enables audio visual communication to at least the operator of a vehicle through at least one of the said plurality speaker means; at least one speaker means responsive for outputting said human voice auditory message selectively broadcast sensed emergency conditions to at least the operator of the said vehicle to enable accident prevention.
 53. View a PSI for monitoring contextual characteristics of a closed system such as a tire system used in a motor vehicle having plurality of tires as claimed in 52, wherein said closed system further includes an apparatus, comprising: a code reader capable for reading information from a sensory platform; a communication unit for communicating with a first information interface having an index and/or one or more other information interfaces mounted in at least a valve stem; an operational unit having one or more adjustable operational parameters associated with one or more operation profiles associated with the closed system; and a controller, coupled wirelessly to the code reader, the communication unit and the operational unit, and arranged to receive information from at least the code reader, and to send request to the first information interface and/or one or more other information interfaces through the communication unit, and to receive at least a response from one or more other information interfaces to enable adjusting the operational parameters of the closed system's operation per unit attachment with the motor vehicle in accordance with the response specification, and wherein the response specification are formatted as transportable documents capable of being analyzed within the vicinity of the vehicle operational environment.
 54. View a PSI for monitoring contextual characteristics of a closed system such as a tire system used in a motor vehicle having plurality of tires as claimed in 53, wherein said closed system further includes an apparatus, and wherein the apparatus and the information interface communicate to at least a wireless network.
 55. View a PSI apparatus having a detection means for detecting contextual characteristics influential to pressure change within a closed system as claimed in 54, wherein said detection means includes at least a detection platform for sensing physical objects and/or contextual characteristics influential to pressure change, and said detection platform having at least electromagnetically elements associated therewith, the platform communicating with information interface, further comprising: a dash board having a communication unit; beneath/above the dash board, an array of controller having voice auditory means; said controller having a control circuitry for (1) causing at least one of the silicon substrate embedded/fused in a micro-fibered material to generate a time-varying interrogation signal, the interrogation signal interacting with sensors/tags disposed on the platform surface within the closed system, (2) receiving a signal indicative of the interrogation signal as affected by the sensors/tags and their proximities to the various silicon substrate embedded/fused in a micro-fibered material, and (3) based on the received signal, determining positions for each of the objects sensed within the closed system; and a microprocessor responsive for enabling wireless communication and voice auditory and/or visual communication on the dash board, wherein said communication enable visual displays relating to the sensed objects derived from the sensors/tags associated therewith, the displays remaining co-located with the sensed objects notwithstanding movement thereof on the sensing surface.
 56. View a PSI apparatus having a detection means for detecting contextual characteristics influential to pressure change within a closed system as claimed in 55, wherein said detection means includes at least a detection platform, and wherein the control circuitry is further configured to determine the context for each of the detected objects, wherein the silicon substrate embedded/fused in a micro-fibered material includes an excitation coil, the excitation coil generating the interrogation signal, the received signal comprising detection signals received from the detection platform, the detection signals representing the interrogation signal as affected by the sensors/tags and their proximities to the sensing surface.
 57. View a PSI apparatus having a detection means for detecting contextual characteristics influential to pressure change within a closed system as claimed in 1, wherein said detection means includes at least a detection platform, and wherein the silicon substrate embedded/fused in a micro-fibered material are affixed to a planar surface and the excitation coil surrounding the detection platform having sensory circuitry, and wherein the sensory circuitry is configured to (1) cause continuous generation of the interrogation signal responsive for tracking the position of objects over time, and (2) determine the fault severity by measuring an average signal strength at a center point of each sensory platform and interpolating between the average signal strengths.
 58. View a PSI apparatus having a detection means for detecting contextual characteristics influential to pressure change within a closed system, wherein said detection means includes at least a detection platform as claimed in 1, wherein the silicon substrate embedded/fused in a micro-fibered material are sequentially caused to generate the interrogation signal, and wherein the received signal comprising a field strength sensed by the coil, the sensed field strength being affected by the sensors/tags and their proximities to said coil.
 59. View a PSI apparatus having a detection means for detecting contextual characteristics influential to pressure change within a closed system, wherein said detection means includes at least a detection platform as claimed in 57, wherein each of the silicon substrate embedded/fused in a micro-fibered material is part of an LC circuit having a measurable electrical characteristic altered by an external condition, the sensory circuitry being further configured to sense contextual characteristics in order to determine safe operational condition of at least a vehicle tire.
 60. View a PSI apparatus having a detection means for detecting contextual characteristics influential to pressure change within a closed system as claimed in 57, wherein said detection means includes at least a detection platform, and wherein the operational condition for said platform is at least one of applied force, temperature, humidity, corrosion, environmental influence, and induced light by at least a foreign object and wherein the influential electrical characteristic is at least one of resonant frequency, harmonic spectra, and at least a Q factor.
 61. A method of view a PSI for monitoring contextual characteristics and for sensing physical objects in a closed system having electromagnetically elements associated therewith as claimed in 44, the method further comprising the steps of: embedding at least a sensor in a silicon substrate; etching the silicon substrate in a micro-fibered material to form a sensory platform; mounting the sensory platform on a tire of a wheel assembly and extending the said platform inwardly from the rim of the wheel assembly toward at least a tire of the wheel assembly such that the sensory platform detects and reports all the said contextual characteristics contained in the wheel assembly; mounting at least one sensor on the sensory platform of a valve stem and away from the rim of the wheel assembly such that at least one sensor does not protrude from the wheel assembly responsive for enabling communication between the tire sensory platform and the operator of a vehicle; causing generation of at least one time-varying interrogation signal within the closed system, the at least one interrogation signal interacting with sensors/tags disposed on the platform surface within the closed system; receiving a signal indicative of the at least one interrogation signal as affected by the sensors/tags; providing a dash board communication means; forming at least one interrogation signal interacting with an electromagnetically actuation-able tag disposed proximate to the dash board, the tag responding wireless to the at least one interrogation signal based on a physical condition associated with an object contained in the closed system; receiving a signal indicative of the at least one interrogation signal as affected by the tag; forming a display visible on the dash board indicative of the physical condition associated with the object, the display remaining co-located with the object notwithstanding movement thereof relative to the dash board; based on the received signal, determining the positions for each of the objects contained within the closed system; displaying information relevant to the sensed objects derived from at least the sensors/tags associated therewith, wherein the display is made visible on the dash board, and co-located with the sensed objects notwithstanding movement thereof on the wheels. communicating said detection signal between said tire sensory platform and said operator of a vehicle in at least a human voice auditory message/signal; providing said voice auditory message in response to broadcasting the specific indication of contextual characteristics detected within the closed system, such as at least temperature change, pressure change, or rim corrosion.
 62. The method of claim 61, further comprising the step of providing a plurality of sensors in a silicon substrate embedded/fused in a micro-fibered material, the silicon substrate in connection to an excitation coil, the excitation coil generating an interrogation signal, the received signal comprising sensing signals received from the sensory circuitry, the sensory circuitry signals representing the interrogation signal as affected by the sensors/tags and their proximities to the sensing surface for enabling the step of determining for each of the sensed objects, at least a characteristic influential to pressure change.
 63. The method of claim 62, wherein the detection platform is located beneath the tire surface and the excitation coil surrounding the sensing silicon substrate embedded/fused in a micro-fibered material.
 64. The method of claim 63 further comprising the steps of: (1) causing continuous generation of the excitation signal through the excitation coil and (2) determining the detection type by measuring the average signal strength at a pressure point of each sensing coil and interpolating between the average signal strengths, the received signal comprising a field strength sensed by the coil generating the interrogation signal, the sensed field strength being affected by the sensors/tags and their proximities to tire internal environment.
 65. A method of sensing physical objects having electromagnetically elements associated therewith of claim 64, the method further comprising the steps of: embedding at least a sensor in a silicon substrate; etching the silicon substrate in a micro-fibered material to form a sensory platform; mounting the sensory platform on a tire of a wheel assembly and extending the said platform inwardly from the rim of the wheel assembly toward at least a tire of the wheel assembly such that the sensory platform detects and reports all the said contextual characteristics contained in the wheel assembly; causing generation of at least one time-varying interrogation signal within the closed system, the at least one interrogation signal interacting with sensors/tags disposed on the platform surface within the closed system, the sensors/tags being configured to respond to the interrogation signal based on physical conditions associated with at least an object, wherein the physical conditions comprises at least one of a weight, a physical manipulation and an environmental condition; receiving a signal indicative of the at least one interrogation signal as affected by the sensors/tags, wherein said signal is communicated to the vehicle operator through a voice auditory means connected to the dashboard; displaying at least a detection type provided by a dash board communication means; forming at least one interrogation signal interacting with an electromagnetically actuation able tag disposed proximate to the dash board, the tag responding wireless to the at least one interrogation signal based on a physical condition associated with an object contained in the closed system; receiving a signal indicative of the at least one interrogation signal as affected by the tag; forming a display visible on the dash board indicative of the physical condition associated with the object, the display remaining co-located with the object notwithstanding movement thereof relative to the dash board. based on the received signal, determining the physical condition for each of the objects within the closed system; and communicating the detection type wirelessly and displaying on the dash board the detection type indicating the physical condition for each of the objects, the displays remaining co-located with the objects notwithstanding movement thereof on the tire.
 66. The method of claim 65, wherein each of the silicon substrate embedded/fused in a micro-fibered material is part of an LC circuit having a measurable electrical characteristic altered by external condition, and further comprising the step of sensing other characteristics in order to determine the safe operating condition of at least a vehicle, wherein the external condition is at least one of applied force, temperature, humidity, environmental influence, and induced light by at least a foreign object.
 67. The method of claim 66, wherein the electrical characteristic is at least one of resonant frequency, harmonic spectra, and Q factor and further comprising the steps of providing the objects with at least electromechanical features for facilitating manipulation to alter the physical condition, and wherein the electromechanical features comprise at least one of thermal control mean s, a dialing means, a slider sealant means, and a switching means.
 68. A method of sensing pressure change and physical objects having electromagnetic elements associated therewith for detecting contextual characteristics influential to pressure change within a closed system as claimed in 67, wherein the detection method includes at least a detection platform, the method comprising the steps of: embedding at least a sensor in a silicon substrate; etching the silicon substrate in a micro-fibered material to form a sensory platform; mounting the sensory platform on a tire of a wheel assembly and extending the said platform inwardly from the rim of the wheel assembly toward at least a tire of the wheel assembly such that the sensory platform detects and reports all the said contextual characteristics contained in the wheel assembly; causing generation of at least one time-varying interrogation signal within the closed system, the at least one interrogation signal interacting with sensors/tags disposed on the platform surface within the closed system, the sensors/tags being configured to respond to the interrogation signal based on physical conditions of associated objects, wherein the physical conditions comprises at least one of a weight, a physical manipulation and an environmental condition; receiving a signal indicative of the at least one interrogation signal as affected by the sensors/tags; providing a dash board communication means: forming at least one interrogation signal interacting with an electromagnetically actuation able tag disposed proximate to the dash board, the tag responding wireless to the at least one interrogation signal based on a physical condition associated with an object contained in the closed system; receiving a signal indicative of the at least one interrogation signal as affected by the tag; forming a display visible on the dash board and indicative of the physical condition associated with the object, the display remaining co-located with the object notwithstanding movement thereof relative to the dash board. based on the received signal, determining the physical condition for each of the objects within the closed system; and communicating detection type wirelessly and displaying on the dash board the said detection type indicating the physical condition for each of the objects, the displays remaining co-located with the objects notwithstanding movement thereof in the tire.
 69. The method of claim 68, wherein the physical condition associated with the object comprises at least one of a weight, a physical manipulation, and an environmental condition and wherein said detection means includes at least a detection platform having electrical characteristics representing an apparatus for detecting contextual characteristics influential to pressure change within a closed system, and wherein the electrical characteristic is at least one of resonant frequency, harmonic spectra, and at least a Q factor.
 70. A microprocessor having a programmable means and simplified programming interface as claimed in claim 1, wherein said programming means suitable for inclusion in a tire replacement scene for creating automation and control system wherein said programmable means changes the active and idle state of a tire detection platform program mode to said new scene state in response to the receipt of a message from a technician, an operator, and other programmable devices by selective actuation de-actuation of the sensory platform input elements, wherein said programmable means enables said platform control system to communicate with at least another communication device such as a control module, such that the activation of a wireless network for monitoring contextual characteristics influential to pressure change within a closed system and for enabling communication of said characteristics to the operator of a vehicle is enabled. 